Network-based system for configuring a system using software programs generated based on a user specification

ABSTRACT

A system and method for online configuration of a measurement system. The user may access a server over a network and specify a desired task, e.g., a measurement task, and receive programs and/or configuration information which are usable to configure the user&#39;s measurement system hardware (and/or software) to perform the desired task. Additionally, if the user does not have the hardware required to perform the task, the required hardware may be sent to the user, along with programs and/or configuration information. The hardware may be reconfigurable hardware, such as an FPGA or a processor/memory based device. In one embodiment, the required hardware may be pre-configured to perform the task before being sent to the user. In another embodiment, the system and method may provide a graphical program in response to receiving the user&#39;s task specification, where the graphical program may be usable by the measurement system to perform the task.

PRIORITY AND CONTINUATION DATA

This application is a divisional application of U.S. patent applicationSer. No. 10/101,508 titled “System and Method for Online Configurationof a Measurement System Using Software Programs Generated Based on aUser Specification” filed Mar. 19, 2002 now, U.S. Pat. No. 6,889,172whose inventors are Brian Sierer, Ganesh Ranganathan, Hugo Andrade andJoseph Peck, and which claims benefit of priority of U.S. provisionalapplication Ser. No. 60/312,359 titled “System and Method for OnlineConfiguration of a Measurement System” filed Aug. 15, 2001, whoseinventors are Brian Sierer, Ganesh Ranganathan, Hugo Andrade and JosephPeck.

FIELD OF THE INVENTION

The present invention relates to the fields of system design, computersoftware, and electronic commerce, and more particularly to onlinespecification, distribution and deployment of configuration informationand/or programs to perform desired tasks. Additionally, applications ofthe invention to measurement and automation applications are described.

DESCRIPTION OF THE RELATED ART

Current models for purchasing software allow the user to purchasepre-existing, static software programs that are targeted to a massaudience. For example, a user can access a web site of numerousdifferent software vendors and purchase and download desiredpre-packaged software programs.

However, current electronic commerce models for purchasing or retrievingsoftware do not have any provision for online specification of a task tofacilitate creation of a custom program. Stated another way, currentelectronic commerce models for purchasing software do not include theability to programmatically generate a program that implements a taskthat has been specified by the user. Therefore, an improved electroniccommerce model is desired for specifying, creating, distributing anddeploying software programs and hardware configuration programs.

One area where users to desire to purchase custom software and/orhardware solutions is in the area of measurement and automation.Scientists and engineers often use measurement or automation systems toperform a variety of functions, including measurement of a physicalphenomena or unit under test (UUT), test and analysis of physicalphenomena, simulation, hardware-in-the-loop testing, process monitoringand control, control of mechanical or electrical machinery, datalogging, laboratory research, and analytical chemistry, to name a fewexamples.

A typical measurement system comprises a computer system with ameasurement device or measurement hardware. The measurement device maybe or include a computer-based instrument, a data acquisition device orboard, a programmable logic device (PLD), a sensor, an actuator, orother type of device for acquiring or generating data. The measurementdevice may be a card or board plugged into one of the I/O slots of thecomputer system, a card or board plugged into a chassis, or an externaldevice. For example, in a common measurement system configuration, themeasurement hardware is coupled to the computer system via other meanssuch as through a VXI (VME extensions for Instrumentation) bus, a PXI(PCI extensions for Instrumentation) bus, a GPIB (General PurposeInterface Bus), a serial port, or parallel port of the computer system.Optionally, the measurement system includes signal conditioning deviceswhich receive the field signals and condition the signals to beacquired.

A measurement system may also typically include transducers, sensors,actuators or other detecting (or generating) means for providing “field”electrical signals representing a process, physical phenomena, equipmentbeing monitored or measured, etc. The field signals are provided to themeasurement hardware.

The measurement hardware is configured and controlled by measurementsoftware executing on the computer system. The measurement software forconfiguring and controlling the measurement system typically comprisestwo portions: the device interface or driver level software and theapplication software, or the application. The driver level softwareserves to interface the measurement hardware to the application. Thedriver level software may be supplied by the manufacturer of themeasurement hardware or by some other third party software vendor. Anexample of measurement or DAQ driver level software is NI-DAQ fromNational Instruments Corporation. The application or client is typicallydeveloped by the user of the measurement system and is tailored to theparticular function or task which the user intends the measurementsystem to perform.

One current area of research and development is the use ofreconfigurable instruments to perform measurement and automation tasks.For example a reconfigurable measurement device may include a FieldProgrammable Gate Array (FPGA) which may be reconfigurable to perform avariety of measurement operations. As another example, a reconfigurablemeasurement device may include a CPU and memory, whereby measurementapplication programs may be stored and executed to perform a variety ofmeasurement operations. Typically, a user who wishes to configure suchan instrument for a particular measurement task may use various toolsand references to determine the correct configuration of the device forthe measurement task. This process may be complicated to perform andprone to error. Additionally, in many cases the user may not have thehardware and/or software necessary to support the task, and may not knowhow to determine the required resources for the task. An e-commercevendor who wishes to provide measurement system components to a user maybe faced with a frustrated customer and high product returns, due toerrors in product selection and configuration.

Therefore, it would be desirable to provide new systems and methods forspecifying and configuring hardware and software for various tasks, suchas measurement tasks. It would further be desirable to provide newelectronic commerce systems to allow vendors to more easily create anddistribute programs (including software programs and hardwareconfiguration programs) to customers.

SUMMARY OF THE INVENTION

Various embodiments for online (or network-based) configuration of asystem are presented. More particularly, various embodiments arepresented for network-based (e.g., Internet-based) specification,creation, and deployment of configuration information and/or programs tousers. Embodiments of the present invention may be used to support newmodels of electronic commerce.

The system may include a client computer system and one or more devicescoupled to the client computer system. The client computer system maycouple to a server over a network. The client computer system may beoperated by a user, and the server may be operated by a vendor tosupport online specification, creation, and deployment of task-specificconfiguration information and/or programs, based on user input.

The client computer system may receive user input specifyingrequirements for a desired task, and the client may provide theserequirements to the server. The server may then determine orprogrammatically generate one or more of: configuration information, oneor more software programs, and/or one or more hardware configurationprograms, in response to or based on the requirements. The configurationinformation, software program(s), and/or hardware configurationprogram(s) may then be transferred to the client computer system and/ordevices to configure the system to perform the task. Embodiments of theinvention may be used in various fields, including measurement,automation, simulation, and others. Various embodiments of the inventionare described below in a measurement application.

In one embodiment, the user of the client computer system may provideuser input to the client computer system indicating one or morerequirements for a measurement task desired to be performed by themeasurement system. For example, the client computer system may displaya graphical user interface (GUI) on its display, and the GUI may receivethe user input indicating the requirements for the measurement task. Inone embodiment, the server may provide the GUI to the client computersystem over the network, and the client computer system may display thereceived GUI. The GUI may display a plurality of panels on the displayto guide the user of the client computer system in providing therequirements for the measurement task. Thus, the GUI may comprise a“task specification wizard” that guides the user to specify a portion orall of task, preferably in a specific domain, such as measurement orautomation.

The requirements may comprise information indicating types of the one ormore measurement devices present in the system, desired operation of theone or more measurement devices, desired signal analysis, etc. Forexample, the requirements may comprise information regarding one or moreof signal type, sampling rate, timing, scaling, analysis function, anddisplay function, among others.

The requirements provided by the user may comprise informationspecifying the measurement devices present in the user's system. Therequirements may also specify one or more target measurement devices tobe configured by the configuration information, software programs,and/or hardware configuration programs (collectively referred to as“products”). The server may also programmatically determine information(requirements) from the system being configured, such as the types ofdevices present, current configuration settings, current installedprograms, etc.

In one embodiment, the client computer system may display a graphicaluser interface (GUI) which iconically illustrates the measurementsystem. The GUI may be generated by software executing on the clientcomputer system or the server computer system. For example, the GUI maydisplay one or more device icons corresponding to respective ones of theone or more measurement devices in the measurement system. The GUI mayalso display connections between the device icons, wherein the displayedconnections correspond to couplings between the measurement device(s)and/or the client computer system. The GUI may further display one ormore icons which represent products to be created and/or deployed in adevice. For example, the GUI may further display one or moreconfiguration icons corresponding to configuration information generated(or to be generated) by the server, one or more program iconscorresponding to programs generated (or to be generated) by the server,and/or one or more hardware configuration program icons corresponding tohardware configuration programs generated (or to be generated) by theserver.

The user may provide input to the GUI specifying the one or more targetmeasurement devices to be configured by the products, either before orafter the products have been provided by the server. The user mayassociate any of these various icons with a device icon, e.g., by usingdrag and drop techniques. For example, where a user associates aconfiguration icon with a device icon, wherein the configuration iconcorresponds to first configuration information, and where the deviceicon corresponds to a first device, the association may operate toinitiate generation of the first configuration information and/or mayoperate to configure the first device with the first configurationinformation. As another example, where a user associates a program iconwith a device icon, wherein the program icon corresponds to a firstprogram, and where the device icon corresponds to a first device, theassociation may operate to initiate generation of the first programand/or deploy or store the first program on the first device. As anotherexample, where a user associates a hardware configuration program iconwith a device icon, wherein the hardware configuration program iconcorresponds to a first hardware configuration program, and where thedevice icon corresponds to a first device having a programmable hardwareelement, the association may operate to initiate generation of the firsthardware configuration program and/or configure the programmablehardware element with the first hardware configuration program.

The client computer system may provide the requirements for themeasurement task to a server over a network, such as the Internet. Inone embodiment, the server may host a vendor configuration site or avendor e-commerce site through which the client computer system and/orthe user may interface with the server.

The server may then determine one or more products, e.g., one or moreof: configuration information, one or more software programs, and/or oneor more hardware configuration programs, in response to the receivedrequirements (and also including any information determined by theserver). Thus the server may store software that is executable toreceive requirements for a measurement task from a client computer,optionally determine capabilities of the measurement system, anddetermine (e.g., programmatically generate) one or more products, e.g.,one or more of: configuration information, one or more softwareprograms, and/or one or more hardware configuration programs, inresponse to the requirements and/or capabilities.

The respective products (e.g., configuration information, softwareprogram(s), and/or hardware configuration program(s)) may then betransferred to the client computer system and deployed on variousdevices. In one embodiment, the user may then deploy the variousreceived products on various devices in the system. For example, theuser may use the configuration diagram GUI to iconically or graphicallydeploy the various products to various devices. Alternatively, theserver may operate to automatically or programmatically deploy theproducts on the devices in the user's system. In this embodiment, wherethe client system displays a configuration diagram, the configurationdiagram may be animated or graphically updated to visually display tothe user the various product deployments that the server is performing.

In one embodiment, the product(s) may comprise a complete, executablesolution. In another embodiment, the products may not be a completesolution (e.g., due to an incomplete specification by the user), and,for example, the user may be required to complete a portion of areceived program. In one embodiment, the products provided by the servermay include development tools that can be installed on the clientcomputer and used to develop a product for the measurement task. In oneembodiment, the server may provide development tools in addition toother products, such as configuration information, software program(s)and/or hardware configuration program(s). In another embodiment, theserver may provide only development tools.

In one embodiment, the server operates to generate and provide one ormore products (configuration information, software programs, and/orhardware configuration programs) without any cost to the user of theclient computer system. In another embodiment, the client computersystem provides payment information to pay for receipt of the products.The payment information may be provided to the server, or to a separatepayment server.

Exemplary embodiments of determining and providing products (e.g.,configuration information, one or more software programs, and/or one ormore hardware configuration programs) are described below.

In a first embodiment, the server may determine configurationinformation in response to the requirements. The configurationinformation may be useable for configuring the measurement system toperform the measurement task. The server may determine the configurationinformation at least in part by retrieving the configuration informationfrom a memory medium based on the requirements. Alternatively, theserver may determine the configuration information at least in part byprogrammatically generating the configuration information in response tothe one or more requirements.

The configuration information may comprise configuration data forconfiguring the measurement system, e.g., parameters for configuring oneor more of the measurement devices. For example, the configurationinformation may be useable to configure one or more of: the clientcomputer system, the one or more measurement devices, and/or one or moreapplication programs. In a measurement application example, theconfiguration information may comprise one or more of sampling rate,gain setting, signal type, timing information, and scaling information,among other types of measurement parameters. The configurationinformation may also include one or more help files and/or one or moreexample files. The example files may include example source code, suchas graphical source code (e.g., a LabVIEW VI) or textual source code,such as C code.

The client computer system may include a configuration software programwhich is operable to receive the configuration information and configurethe measurement system using the configuration information.Alternatively, in addition to the configuration information, the servermay further determine and provide one or more programs that areexecutable by the client computer system to configure the measurementsystem with the configuration information to perform the measurementtask.

Thus, in various embodiments, the configuration information maycomprise:

-   -   configuration data for configuring the measurement system to        perform the measurement task, where the client computer system        includes a configuration software program which is operable to        receive the configuration data and configure the measurement        system;    -   configuration data and a configuration program (e.g., an        installer) which is executable by the client computer system to        configure one or more of the client computer system and the one        or more measurement devices using the configuration data; and/or    -   a self-executing program file which operates to configure one or        both of the client computer system and the one or more        measurement devices with the configuration information.

After the server determines the configuration information, the servermay provide the configuration information to the measurement system overthe network. The measurement system may then be configured using theconfiguration information, wherein the measurement system may beoperable to perform the measurement task after being configured usingthe configuration information. For example, the client computer systemmay receive the configuration parameters and configure one or moremeasurement devices, the client computer system, and/or one or moresoftware programs accordingly.

After being configured using the configuration information, themeasurement system may operate to perform the measurement task. It isnoted that other programs, either developed by the user or provided bythe server, may be used to perform the measurement task. In ameasurement application example, the measurement system may receive asignal from a signal source, and the one or more measurement devices mayoperate according to the configuration information to analyze thesignal.

In a second embodiment, the server may determine one or more softwareprograms in response to the requirements. The software program(s) may beexecutable by the measurement system to perform the measurement task.

The software program(s) may comprise executable code (machine languagecode) which is executable by the measurement system to perform themeasurement task. Alternatively, the software program(s) may comprisesource code which is one or more of: 1) compilable and executable, or 2)interpretable, by the measurement system to perform the measurementtask. In one embodiment, the software program(s) may comprise at leastone graphical program. In this embodiment, the measurement system maystore a graphical program execution engine for executing the graphicalprogram to perform the measurement task. The software program(s) mayalso comprise any combination of the above, e.g., one or more executablecode files, one or more source programs in a text-based programmingenvironment, and/or one or more graphical programs.

The server may determine the software program(s) at least in part byretrieving the programs from a memory medium based on the requirements.Alternatively, or in addition, the server may determine the softwareprogram(s) at least in part by programmatically generating the programsbased on the requirements. In one embodiment, the server mayprogrammatically generate a graphical program in response to therequirements. For example, in response to receiving the one or morerequirements for the task, the server may generate a LabVIEW graphicalprogram developed under the National Instruments LabVIEW graphicaldevelopment environment, which is usable to perform the task. Thegenerated graphical program may then be sent to the client computersystem.

After the server determines the software program(s), the server mayprovide the software program(s) to the measurement system over thenetwork. The software program(s) may be deployed in the measurementsystem in various respective locations. For example, the softwareprogram(s) may be executable by the client computer system.Alternatively, or in addition, a measurement device may have a processorand memory for executing the program(s). In one embodiment, the providedsoftware program(s) may not be complete and/or executable, and the usermay be required to complete the program in some way prior to executionor deployment on the various devices. In one embodiment, the server mayfurther provide software development tools (e.g., LabVIEW) to aid theuser in completing the received program.

After the software program(s) are deployed in the system, themeasurement system may execute the software program(s) to perform themeasurement task. In a measurement application example, the one or moremeasurement devices and/or client computer system may execute thesoftware program(s) to receive a signal from a signal source and analyzethe signal.

Where the received program is a graphical program, the client mayexecute a graphical program execution engine (e.g., LabVIEW or LabVIEWRT) to execute the graphical program to perform the specified task. Inother words, the measurement system may include the graphical programexecution engine, thereby facilitating native execution of the graphicalprogram on the system to perform the task.

In another embodiment, the graphical program may be converted to anexecutable format (machine code), and run or executed under a real timeoperating system to perform the task. As another example, the graphicalprogram may be converted to a different or “lower level” source codeformat, such as C, C++, FORTRAN, Basic, Java, etc., then compiled orinterpreted for execution under an operating system, such as a real timeoperating system. In yet another embodiment, the graphical program maybe converted to a hardware configuration program at the client computerand used to configure a programmable hardware element in the clientsystem.

In a third embodiment, the server may determine one or more hardwareconfiguration programs in response to the requirements. The one or morehardware configuration programs may be used to configure a programmablehardware element in the measurement system to perform the measurementtask.

The server may determine the hardware configuration program(s) at leastin part by retrieving the programs from a memory medium based on therequirements. Alternatively, or in addition, the server may determinethe hardware configuration program(s) at least in part byprogrammatically generating the hardware configuration programs based onthe requirements.

A hardware configuration program may be generated in various ways. Forexample, the server may programmatically generate a program (e.g., atext-based program or a graphical program) in response to therequirements, and then programmatically generate the hardwareconfiguration program based on the program. As another example, theserver may programmatically generate an intermediate specification ordata structure representing the desired operation, and thenprogrammatically generate the hardware configuration program based onthis intermediate specification or data structure.

After the server determines the hardware configuration program(s), theserver may provide the hardware configuration program(s) to themeasurement system over the network. The hardware configurationprogram(s) may be deployed in the measurement system in variousrespective locations. For example, a measurement device may have aprogrammable hardware element that is configurable using the program(s).The user may choose to deploy the hardware configuration program(s) tovarious devices, e.g., using a GUI based configuration diagram. In oneembodiment, the provided hardware configuration program(s) may not becomplete, and the user may be required to complete the hardwareconfiguration program in some way prior to deployment on a programmablehardware element. In one embodiment, the server may further providehardware configuration program development tools to aid the user incompleting the received program.

After the programmable hardware element in the measurement system isconfigured with the hardware configuration program, the programmablehardware element may operate according to the hardware configurationprogram to perform at least a portion of the measurement task. In ameasurement application example, a measurement device having aprogrammable hardware element that has been configured according to thehardware configuration program may operate accordingly to receive asignal from a signal source and analyze the signal.

In one embodiment, if the server determines, either programmatically orbased on user input, that the that the client system does not include anecessary measurement hardware device for performing the task, and ifthe user agrees to purchase the device, the server may transmitinformation to a manufacturer indicating that the measurement hardwaredevice should be shipped to the user. For example, the server maydisplay a dialog box to the user indicating that a hardware device isneeded and asking the user if he/she desires to purchase this hardwaredevice. The manufacturer may then send the measurement hardware deviceto the user.

Where the server is operated by the hardware manufacturer, the servermay simply send the product order to a hardware fulfillment server forprocessing. For example, National Instruments may operate a server whichis operable to receive user requirements specifying a task and determine(or create) products that perform this task as described above, and mayalso include a hardware fulfillment server that interfaces tomanufacturing for providing necessary hardware products to users.

In one embodiment, the server may also transmit the products that havebeen determined to the hardware fulfillment server (manufacturer) sothat the hardware device can be appropriately configured before beingsent to the user. Thus, the manufacturer may configure the measurementhardware device with the respective products, e.g., by storing asoftware program on the device or by configuring a programmable hardwareelement on the device, prior to sending the indicated hardware device tothe user. In this instance, the configured measurement hardware devicesent to the user may already be operable to perform the desiredmeasurement task. In another embodiment, the one or more products may beprovided to the user for configuring the hardware device when it isreceived. The products may be provided to the client computer systemover the Internet, via a CD ROM sent by mail, or by any othertransmission means. In another embodiment, the server may provide theappropriate development tools to the client computer system to enablethe user to easily develop custom solutions.

In one embodiment, the user may provide information regarding thecurrent configuration and products (e.g., programs) present in theclient system to the server for analysis. For example, the user canprovide a snapshot of the configuration of the measurement system andthe software programs (e.g., a LabVIEW VI) present in the system. Theserver may receive this information and execute software to makeproposed suggestions to the user or actual modifications to the clientsystem's configuration or programs. The modified configuration orprograms may then be returned to the client system for use. This type ofbi-directional analysis may be performed one or more times.Alternatively, the server may programmatically analyze a product, suchas a program (e.g., a graphical program), resident on a client systemand make proposed changes (including additions) to the program based onrequirements specified by the user.

Thus, in various embodiments, the present invention provides systems andmethods whereby a user may specify a measurement task over a network,and various products may be generated or modified which are usable toconfigure a measurement system to perform the measurement task. Theproducts may then be sent to the user for configuration on or deploymentto the client system. Additionally, if the user does not have therequired measurement hardware to perform the measurement task, therequired hardware may be automatically sent to the user, and may even bepre-configured with the appropriate products to perform the measurementtask. Further, the user can provide information on the currentconfiguration and products present in the client system for analysis bythe server and further modifications.

BRIEF DESCRIPTION OF THE DRAWINGS

A better understanding of the present invention can be obtained when thefollowing detailed description of the preferred embodiment is consideredin conjunction with the following drawings, in which:

FIG. 1 illustrates a client/server system for configuration of ameasurement system, according to one embodiment;

FIGS. 2A-2C illustrate representative instrumentation and processcontrol systems including various I/O interface options;

FIG. 3 is a block diagram of the client computer system of FIGS. 1, 2Aand 2B, according to one embodiment;

FIGS. 4A-4D are block diagrams of reconfigurable instruments, accordingto various embodiments;

FIG. 5 is a flowchart diagram illustrating network-based specification,generation and deployment of products according to one embodiment;

FIG. 6A is a flowchart diagram illustrating network-based specification,generation and deployment of configuration information according to oneembodiment;

FIG. 6B is a flowchart diagram illustrating network-based specification,generation and deployment of software programs according to oneembodiment;

FIG. 6C is a flowchart diagram illustrating network-based specification,generation and deployment of hardware configuration programs accordingto one embodiment;

FIG. 7 is a flowchart diagram illustrating a method of determiningconfiguration information based on received requirements;

FIG. 8A is a flowchart diagram illustrating a method of determiningprograms based on received requirements which includes retrieving theprograms from a database;

FIG. 8B is a flowchart diagram illustrating a method of determiningprograms by programmatically generating the programs based on thereceived requirements;

FIGS. 9A and 9B are flowchart diagrams illustrating methods ofprogrammatically generating a hardware configuration program;

FIG. 10 is a flowchart diagram illustrating network-based specification,distribution and deployment of products which may include providinghardware devices to the user;

FIG. 11 is a flowchart diagram illustrating network-based specification,generation and deployment of a graphical program;

FIGS. 12A-12B illustrate two embodiments of a system for taskspecification and system configuration, according to one embodiment;

FIG. 13 illustrates a graphical user interface (GUI) of a measurementtask specifier interface, according to one embodiment; and

FIG. 14 illustrates a graphical user interface for deploying products ondevices.

While the invention is susceptible to various modifications andalternative forms, specific embodiments thereof are shown by way ofexample in the drawings and are herein described in detail. It should beunderstood, however, that the drawings and detailed description theretoare not intended to limit the invention to the particular formdisclosed, but on the contrary, the intention is to cover allmodifications, equivalents and alternatives falling within the spiritand scope of the present invention as defined by the appended claims.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Incorporation by Reference

The following references are hereby incorporated by reference in theirentirety as though fully and completely set forth herein:

U.S. Pat. No. 4,914,568 titled “Graphical System for Modeling a Processand Associated Method,” issued on Apr. 3, 1990.

U.S. Pat. No. 5,481,741 titled “Method and Apparatus for ProvidingAttribute Nodes in a Graphical Data Flow Environment”.

U.S. Pat. No. 6,173,438 titled “Embedded Graphical Programming System”filed Aug. 18, 1997.

U.S. Pat. No. 6,219,628 titled “System and Method for Configuring anInstrument to Perform Measurement Functions Utilizing Conversion ofGraphical Programs into Hardware Implementations,” filed Aug. 18, 1997.

U.S. patent application Ser. No. 09/617,600 titled “GraphicalProgramming System with Distributed Block Diagram Execution and FrontPanel Display,” filed Jun. 13, 2000, currently pending.

U.S. patent application Ser. No. 09/745,023 titled “System and Methodfor Programmatically Generating a Graphical Program in Response toProgram Information,” filed Dec. 20, 2000, currently pending.

U.S. Patent Application Ser. No. 60/301,785 titled “Measurement SystemSoftware Architecture for Easily Creating High-Performance MeasurementApplications,” filed Jun. 29, 2001, currently pending.

U.S. patent application Ser. No. 10/008,792 titled “Measurement SystemSoftware Architecture for Easily Creating High-Performance MeasurementApplications,” filed Nov. 13, 2001, currently pending.

U.S. Patent Application Ser. No. 60/312,242 titled “System and Methodfor Graphically Creating, Deploying and Executing Programs in aDistributed System” filed Aug. 14, 2001, currently pending.

U.S. patent application Ser. No. 10/058,150 titled “ReconfigurableMeasurement System Utilizing a Programmable Hardware Element and FixedHardware Resources”, filed on Oct. 29, 2001, currently pending.

U.S. patent application Ser. No. 09/587,682 titled “System and Methodfor Automatically Generating a Graphical Program to Perform an ImageProcessing Algorithm” filed on Jun. 5, 2000, which issued as U.S. Pat.No. 6,763,515 on Jul. 13, 2004.

The LabVIEW graphical programming manuals, including the “G ProgrammingReference Manual”, available from National Instruments Corporation, arealso hereby incorporated by reference in their entirety.

FIG. 1—A Client/Server System

FIG. 1 illustrates a client/server system suitable for implementingvarious embodiments of the present invention. As FIG. 1 shows, a clientcomputer system 102 may be coupled to a server computer system 103through a network 104, such as the Internet. The client computer system102 may include software, such as browser software, for accessing andcommunicating with the server computer system 103. Each of the clientcomputer system 102 and server computer system 103 may include networkinterface devices and network ports for communicating on a network. Theclient computer system 102 may also be coupled to, or comprise, one ormore devices, where the client computer system 102 and the one or moredevices compose a system. In one embodiment, the device is a measurementdevice, and the client computer system 102 and the one or moremeasurement devices compose a measurement system. For example, theclient computer system 102 may couple to any of the measurement devicesshown in FIGS. 2A and 2B.

As described below, the client computer system 102 and/or one or moredevices coupled to the client computer system may be configurable byreceiving one or more products over a network in response to taskinformation or requirements provided by the client computer system 102.In one embodiment, the client computer system 102 may be used forinterfacing to the server 103 and used for configuring a device that iscoupled to the network 104, but is not connected (or directly coupled)to the client computer system 102.

As used herein, the term “product” includes one or more of thefollowing: configuration information, one or more software programs,and/or one or more hardware configuration programs. Thus the term“product” includes any of various types of programs or data that may beused to configure a computer system or device.

As used herein, the term “device” is intended to include any of varioustypes of devices that include one or more of: 1) a processor and memory;and/or 2) a programmable hardware element or reconfigurable logic.Exemplary types of processors include a conventional microprocessor orCPU (such as an X86, PowerPC, SunSparc, etc.), a digital signalprocessor (DSP), microcontroller, or other type of processor. Exemplarytypes of programmable hardware elements include a programmable logicdevice (PLD), e.g., an FPGA (field programmable gate array), or othertypes of reconfigurable logic.

Exemplary types of devices include computer systems, network devices,personal digital assistants (PDAs), television systems, multimediadevices, measurement devices, instruments, industrial automationdevices, process control devices, smart data acquisition devices, smartsensors (including smart cameras), smart actuators, video devices (e.g.,digital cameras, digital video cameras), audio devices, computerperipherals, telephones, appliances, or other processor-based orprogrammable hardware-based devices. Exemplary measurement andautomation devices include any of the devices shown in FIGS. 2A and 2B.Exemplary network devices include network interface cards, routers,bridges, switches, hubs, etc. Exemplary measurement devices includecamera, video cameras, sound devices, etc.

As used herein, the term “measurement device” is intended to include anyof various types of devices which performs at least a portion of ameasurement or automation function. The term “measurement device”includes any of the instruments or measurement devices shown in FIGS. 2Aand 2B, as well as other measurement devices, such as smart sensors(including smart cameras), sensors, transducers, etc. A “measurementdevice” may comprise a client computer system which executes measurementsoftware. The client computer system may also couple to one or moreother measurement devices, e.g., an internal measurement device (e.g.,configured as a plug-in card), or external measurement devices.

The terms “reconfigurable measurement device”, “smart measurementdevice” or “reconfigurable instrument” may be used to refer to a“measurement device” as described above. For more information on areconfigurable measurement device or reconfigurable instrument whichincludes a processor and memory, please see U.S. Pat. No. 6,173,438which was incorporated by reference above. For more information on areconfigurable measurement device or reconfigurable instrument whichincludes a programmable hardware element or reconfigurable hardware,e.g., an FPGA, please see U.S. Pat. No. 6,219,628 which was incorporatedby reference above.

As used herein, the term “programmable hardware element” is intended toinclude various types of programmable hardware, reconfigurable hardware,programmable logic, or field-programmable devices (FPDs), such as one ormore FPGAs (Field Programmable Gate Arrays), or one or more PLDs(Programmable Logic Devices), such as one or more Simple PLDs (SPLDs) orone or more Complex PLDs (CPLDs), or other types of programmablehardware.

As used herein, the term “program” is intended to include: 1) a softwareprogram, or 2) a hardware configuration program, useable for configuringa programmable hardware element or reconfigurable logic. A “softwareprogram” may be any type of code and/or data that may be stored in amemory medium and executed by a processor. Exemplary software programsinclude programs written in text-based programming languages, such as C,C++, Pascal, FORTRAN, Cobol, Java, etc.; programs written in assemblylanguage; programs written in graphical programming languages; programsthat have been compiled to machine language; scripts; and other types ofexecutable software. Exemplary “hardware configuration programs” includenetlists and bit files for programmable hardware elements such as FPGAsand other reconfigurable hardware.

As used herein, the term “configuration information” may includeconfiguration data, such as hardware configuration settings orparameters, help files, documentation, etc. Configuration data istypically used to configure one or more devices for desired operation.

As used herein, the term “graphical program” or “block diagram” isintended to include a program comprising graphical code. The term“graphical code” refers to two or more interconnected nodes or icons,wherein the interconnected nodes or icons may visually indicate thefunctionality of the program. The nodes may be connected in one or moreof a data flow, control flow, and/or execution flow format. The nodesmay also be connected in a “signal flow” format, which is a subset ofdata flow. Thus the terms “graphical program” or “block diagram” areeach intended to include a program comprising a plurality ofinterconnected nodes or icons which visually indicate the functionalityof the program.

A graphical program may also comprise a user interface or front panel.The user interface portion may be contained in the block diagram or maybe contained in one or more separate panels or windows. The userinterface of a graphical program may include various graphical userinterface elements or front panel objects, such as user interfacecontrols and/or indicators, that represent or display the respectiveinput and/or output that will be used by the graphical program or VI(virtual instrument), and may include other icons which representdevices being controlled. The user interface or front panel may becomprised in a single window of user interface elements, or may comprisea plurality of individual windows each having one or more user interfaceelements, wherein the individual windows may optionally be tiledtogether. As another example, the user interface or front panel maycomprise user interface or front panel objects, e.g., the GUI, embeddedin the block diagram. The user interface of a graphical program maydisplay only output, only input, or both input and output. In someembodiments the user interface or front panel of a graphical program mayenable the user to interactively control or manipulate the input beingprovided to the graphical program during program execution.

Examples of graphical program development environments that may be usedto create graphical programs include LabVIEW, DasyLab, and DiaDem fromNational Instruments, VEE from Agilent, WiT from Coreco, Vision ProgramManager from PPT Vision, SoftWIRE from Measurement Computing, Simulinkfrom the MathWorks, Sanscript from Northwoods Software, Khoros fromKhoral Research, SnapMaster from HEM Data, VisSim from Visual Solutions,ObjectBench by SES (Scientific and Engineering Software), and VisiDAQfrom Advantech, among others. In the preferred embodiment, the systemuses the LabVIEW graphical programming system available from NationalInstruments.

A program for performing an instrumentation, measurement, automation orsimulation function, such as measuring phenomena of a Unit Under Test(UUT) or device, controlling or modeling instruments, controlling ormeasuring a system or process, or for designing, modeling or simulatingdevices, may be referred to as a virtual instrument (VI).

FIGS. 2A and 2B—Instrumentation and Industrial Automation Systems

FIGS. 2A and 2B illustrate exemplary measurement and automation systems.As used herein, the term “measurement system” is intended to include thetypes of measurement systems and automation systems shown in FIGS. 2A,2B and 2C, as well as other types of systems. For example, although notshown in FIGS. 2A-2C, a measurement system may comprise one or moretraditional “box” instruments, such as those available from Agilent orTektronix, which may couple to a computer system or which include aprocessor, memory and display capabilities, preferably including webbrowser capabilities.

The measurement systems shown in FIGS. 2A-2C may be operable to receiveand be configured by configuration information. The measurement systemsshown in FIGS. 2A-2C may be operable to receive and execute programs,e.g., software programs and/or hardware configuration programs,according to one embodiment of the invention. In accordance with oneembodiment of the invention, the present system and method allows usersto more easily configure and/or program their measurement systems. Forexample, a user can specify one or more of measurement, control,simulation, and automation tasks (collectively referred to as“measurement tasks”) and provide this specification to a server computersystem. The server can then determine (e.g., programmatically create)products, such as configuration information or programs, and providesthese products to the measurement system to configure the measurementsystem to implement desired tasks.

As used herein, the term “measurement system” is intended to include aninstrumentation system such as that shown in FIGS. 2A and 2C, anindustrial automation system such as that shown in FIG. 2B, or amodeling or simulation system involved with the design, validation ortesting of a product involving “real world I/O”, i.e., the acquisitionor generation of data to/from a model or simulation of a device orproduct being designed, validated or tested, such as hardware-in-theloop simulation and rapid control prototyping. The term “measurement”may include one or more of instrumentation, measurement, dataacquisition, automation, control, and simulation, includinghardware-in-the-loop simulation and rapid control prototyping.

FIG. 2A illustrates an exemplary measurement system or instrumentationsystem 100. The system 100 may comprise a host computer 102 whichconnects to one or more measurement devices or instruments. The hostcomputer 102 may comprise a CPU, a display, memory, and one or moreinput devices such as a mouse or keyboard, as shown. The host computer102 connects through the one or more instruments to analyze, measure, orcontrol a unit under test (UUT) or process 150.

The host computer 102 may execute a program which interacts with orcontrols the one or more instruments. The one or more instruments mayinclude a GPIB instrument 112 and associated GPIB interface card 122, adata acquisition board 114 and associated signal conditioning circuitry124, a VXI instrument 116, a PXI instrument 118, a video device orcamera 132 and associated image acquisition card 134, a motion controldevice 136 and associated motion control interface card 138, and/or oneor more computer based instrument cards 142 and 143, includingreconfigurable instruments, among other types of devices. Variousexamples of reconfigurable instruments or measurement devices aredescribed below with reference to FIGS. 4A-4D.

The GPIB instrument 112 may be coupled to the computer 102 via the GPIBinterface card 122 provided by the computer 102. In a similar manner,the video device 132 may be coupled to the computer 102 via the imageacquisition card 134, and the motion control device 136 may be coupledto the computer 102 through the motion control interface card 138. Thedata acquisition board 114 may be coupled to the computer 102, and mayinterface through signal conditioning circuitry 124 to the UUT. Thesignal conditioning circuitry 124 may comprise an SCXI (SignalConditioning extensions for Instrumentation) chassis comprising one ormore SCXI modules 126.

The GPIB card 122, the image acquisition card 134, the motion controlinterface card 138, and the DAQ card 114 are typically plugged in to anI/O slot in the computer 102, such as a PCI bus slot, a PC Card slot, oran ISA, EISA or MicroChannel bus slot provided by the computer 102.However, these cards 122, 134, 138 and 114 are shown external tocomputer 102 for illustrative purposes.

The VXI chassis or instrument 116 may be coupled to the computer 102 viaa VXI bus, MM bus, or other serial or parallel bus provided by thecomputer 102. The computer 102 may include VM interface logic, such as aVXI, MXI or GPIB interface card (not shown), which interfaces to the VXIchassis 116. The PXI chassis or instrument may be coupled to thecomputer 102 through the computer's PCI bus.

A serial instrument (not shown) may also be coupled to the computer 102through a serial port, such as an RS-232 port, USB (Universal Serialbus) or IEEE 1394 or 1394.2 bus, provided by the computer 102.

In addition to the above measurement devices, other types of measurementdevices include smart sensors (including smart cameras).

In typical instrumentation systems an instrument of each interface typemay not be present, and in fact many systems may only have one or moreinstruments of a single interface type, such as only GPIB instruments.The instruments are coupled to the unit under test (UUT) or process 150,or are coupled to receive field signals, typically generated bytransducers. The system 100 may be used in a data acquisition andcontrol application, in a test and measurement application, a processcontrol application, a man-machine interface application, or asimulation application.

FIG. 2B illustrates an exemplary industrial automation system 160. Theindustrial automation system 160 may be similar to the instrumentationor test and measurement system 100 shown in FIG. 2A. Elements which aresimilar or identical to elements in FIG. 2A have the same referencenumerals for convenience. The system 160 comprises a computer 102 whichconnects to one or more devices or instruments. The computer 102comprises a CPU, a display screen, memory, and one or more input devicessuch as a mouse or keyboard as shown. The computer 102 connects throughthe one or more devices to a process or device 150 to perform anautomation function, such as MMI (Man Machine Interface), SCADA(Supervisory Control and Data Acquisition), portable or distributed dataacquisition, process control, advanced analysis, or other control. InFIG. 2B, the computer 102 may execute a program that is involved withthe automation function performed by the automation system 160.

The one or more devices may include a data acquisition board 114 andassociated signal conditioning circuitry 124, a PXI instrument 118, avideo device 132 and associated image acquisition card 134, a motioncontrol device 136 and associated motion control interface card 138, afieldbus device 170 and associated fieldbus interface card 172, a PLC(Programmable Logic Controller) 176, a serial instrument 182 andassociated serial interface card 184, or a distributed data acquisitionsystem, such as the Fieldpoint system available from NationalInstruments, as well as a reconfigurable instrument, describe above,among other types of devices. As mentioned above, various examples ofreconfigurable instruments or measurement devices are described belowwith reference to FIGS. 4A-4D.

The DAQ card 114, the PXI chassis 118, the video device 132, and theimage acquisition card 136 may be connected to the computer 102 asdescribed above. The serial instrument 182 may be coupled to thecomputer 102 through a serial interface card 184, or through a serialport, such as an RS-232 port, provided by the computer 102. The PLC 176may couple to the computer 102 through a serial port, Ethernet port, ora proprietary interface. The fieldbus interface card 172 may becomprised in the computer 102 and interfaces through a fieldbus networkto one or more fieldbus devices. Each of the DAQ card 114, the serialcard 184, the fieldbus card 172, the image acquisition card 134, and themotion control card 138 are typically plugged in to an I/O slot in thecomputer 102 as described above. However, these cards 114, 184, 172,134, and 138 are shown external to computer 102 for illustrativepurposes.

In typical industrial automation systems a device will not be present ofeach interface type, and in fact many systems may only have one or moredevices of a single interface type, such as only PLCs. The devices arecoupled to the device or process 150.

FIG. 2C illustrates one embodiment of a measurement system in which thecomputer system 102 couples to an instrumentation card or measurementdevice 143. In one embodiment, the measurement device 143 may beprogrammed or configured to operate as any of a variety of measurementdevices or instruments.

As described above, the term “measurement device” or “reconfigurableinstrument” may refer to a device with a processor, e.g., a CPU, coupledto a memory, which is operable to store and execute one or more softwareprograms to perform a measurement task. By executing differentmeasurement application programs, the device may operate as a variety ofdifferent measurement devices. The term “measurement device” or“reconfigurable instrument” may also refer to a device which comprises aprogrammable hardware element (also called reconfigurable hardware),such as a Field Programmable Gate Array (FPGA), which may be(re)programmed with a hardware configuration program, such as a bit filegenerated from a netlist or hardware description, to function as any ofa variety of measurement devices. A measurement device or reconfigurableinstrument may also refer to a device which includes combinations of oneor more processors, one or more programmable hardware elements, orvarious combinations, such as multiple FPGAs, multiple CPU/memoryelements, and/or combinations of both FPGA and CPU/memory elements.

As FIG. 2C also shows, the instrumentation card 143 may be operable tocouple to a Unit Under Test (UUT) 130. Thus, the computer system 102 andthe instrumentation card 143 may compose a measurement system which isoperable to measure one or more attributes of the UUT to analyze orcharacterize the UUT.

For illustration purposes, the instrumentation card 143 is shown outsidethe computer 102. However, the instrumentation card 143 may be locatedwithin the chassis of the computer 102. For example, one or moreinstrumentation cards 143 may be coupled to the computer 102 by one ormore I/O slots (not shown) provided by the computer 102 and to the UUT130 (and/or to receive field signals) through one or more sensors ortransducers (also not shown). The computer 102 may connect through theone or more instrumentation cards 143 to analyze, measure or control aunit under test (UUT) or process under test 130.

In another embodiment, one or more instrumentation cards 143 may becomprised in a separate chassis and coupled to the computer 102. Forexample, the one or more instrumentation cards 143 may be comprised in aPXI chassis, a VXI chassis or other similar form factor. The computer102 may also be comprised in a PXI chassis or VXI chassis.

The system 100 may be used in a data acquisition and controlapplication, in a test and/or measurement application, an automationapplication, a process control application, a man-machine interfaceapplication, or a simulation application, including ahardware-in-the-loop simulation application or a rapid controlprototyping application, among others.

The computer system 102 and/or one or more of the instruments or devices(e.g., reconfigurable instruments) may include a memory medium (ormemory mediums) on which data and software according to the presentinvention may be stored. The client computer system memory medium maystore (for execution by the CPU) a web browser for accessing othercomputers on the Internet, and configuration information and/or programsreceived from a server computer system, as well as other types ofsoftware. The client computer system memory medium may store aconfiguration program. An exemplary configuration program formeasurement applications is Measurement & Automation Explorer (MAX) fromNational Instruments Corporation.

The server computer system 103 may comprise a CPU and a memory medium.The server memory medium may store software (for execution by the CPU)for determining products (configuration information, software programs,and/or hardware configuration programs) in response to requirementinformation received from a client computer system, and for providingdetermined products to the client computer system. The server memorymedium may store web server software for hosting a web site that isaccessible by the client computer system. The server memory medium mayalso store electronic commerce software for conducting electroniccommerce with the client computer system (e.g., receiving payment fromthe client computer system).

Either of the client or server memory mediums may store taskspecification software (e.g., a measurement task specifier) for enablinga user to specify requirements or a specification of a task. Either ofthe client or server memory mediums may also store a program forgenerating a configuration diagram that graphically illustrates themeasurement system in which the client computer system 102 is a part.

The software comprised in the server for determining products maycomprise measurement task specification software including an expertsystem which may include a plurality of experts. In one embodiment, themeasurement task specification software may be operable to receive userinput specifying a measurement task and to generate a measurement taskspecification. The expert system may be operable to analyze themeasurement task specification and determine one or more hardware and/orsoftware implementations to perform the specified measurement task. Inone embodiment, the server computer system 103 may also store a runtimebuilder and a plurality of measurement primitives, described below.Additionally, the server memory medium(s) may store various productsproduced by or with these software components, such as a measurementtask specification, various types of programs, including softwareprograms, e.g., graphical programs, hardware configuration programs(e.g., bit files), configuration information for software and/orhardware, etc. In one embodiment, the server computer system 103 mayalso generate or include a runtime specification, and a runtime,described in more detail below. More information on an embodiment of theproduct determination software may be found in U.S. patent applicationSer. No. 10/008,792 titled “Measurement System Software Architecture forEasily Creating High-Performance Measurement Applications,” filed Nov.13, 2001.

In some embodiments, the server computer system 103 may comprise aplurality of interconnected server computers. For example, one servercomputer may be used to interface with client computer systems over thenetwork, such as the computer system 102, while another server computermay be used to store and manage a database. In addition, one servercomputer may be used to interface with client computer systems over thenetwork (and possibly store programs for downloading to client computersystems), and other servers may also store programs useable fordownloading to client computer systems. A separate server may alsooperate as an e-commerce server for requesting and receiving paymentinformation.

The term “memory medium” is intended to include an installation medium,e.g., a CD-ROM, floppy disks 104, or tape device; a computer systemmemory or random access memory such as DRAM, SRAM, EDO RAM, RRAM, etc.;or a non-volatile memory such as a magnetic media, e.g., a hard drive,or optical storage. The memory medium may comprise other types of memoryas well, or combinations thereof. In addition, the memory medium may belocated in a first computer in which software programs are stored and/orexecuted, or may be located in a second different computer whichconnects to the first computer over a network, such as the Internet. Inthe latter instance, the second computer provides the programinstructions to the first computer for execution.

In one embodiment, the programs and methods as described herein may bedesigned for measurement systems, including data acquisition/generation,analysis, and/or display; automation systems; simulation systems;systems for controlling, modeling, or simulating instrumentation orindustrial automation hardware; and systems for controlling, modeling orsimulating systems or devices being designed, prototyped, validated ortested, including hardware-in-the-loop systems and rapid controlprototyping systems. However, it is noted that the present invention canbe used for a plethora of applications and is not limited to measurementor industrial automation applications. In other words, FIGS. 2A-2C andthe embodiments described below are exemplary only, and the programs andmethods may be used for any of various purposes and may be stored in andexecute on any of various types of systems to perform any of variousapplications. For example, embodiments of the present invention may beused to purchase or distribute programs for any general purposeapplication. Thus the methods described herein provide an e-commercemodel for selling or distributing programs, such as software programs,in any of various fields, particularly fields that require customprogram generation.

FIG. 3—Client Computer System Block Diagram

FIG. 3 is an exemplary block diagram of the client computer systemillustrated in FIGS. 1, 2A, 2B, and 2C. It is noted that any type ofcomputer system configuration or architecture can be used in conjunctionwith the system and method described herein, as desired, and FIG. 3illustrates a representative PC embodiment. It is also noted that thecomputer system may be a general purpose computer system such asillustrated in FIGS. 2A and 2B, a computer implemented on a VXI cardinstalled in a VXI chassis, a computer implemented on a PXI cardinstalled in a PXI chassis, or other types of embodiments. The elementsof a computer not necessary to understand the present invention havebeen omitted for simplicity.

The computer 102 includes at least one central processing unit or CPU106 which is coupled to a memory 108 and a bus controller 109. The CPU106 may be any of various types, including an x86 processor, e.g., aPentium class, a PowerPC processor, a CPU from the SPARC family of RISCprocessors, as well as others. Memory 108 is also coupled to the buscontroller 109. The memory 108 may store one or more computer programsor libraries according to one embodiment of the present invention. Thememory 108 also stores operating system software, i.e., software foroperation of the computer system, as is well known to those skilled inthe art.

The bus controller 109 (or bus bridge logic) may be coupled to anexpansion or input/output bus 110. The expansion bus 110 is preferablythe PCI (Peripheral Component Interconnect) expansion bus, althoughother bus types can be used. The expansion bus 110 may include slots forvarious devices such as a measurement device or reconfigurableinstrument 143, as well as other devices as desired. The computer 102may further comprise a video display subsystem 180 and hard drive 182coupled to the expansion bus 170.

It is noted that although the measurement device shown is thereconfigurable instrument 143 of FIGS. 2A and 2C, the measurement device143 could be any of the devices of FIGS. 2A and 2B, or any othermeasurement device as desired.

FIGS. 4A-4D—Block Diagrams of Reconfigurable Instruments

FIGS. 4A-4D are block diagrams of various exemplary embodiments of areconfigurable instrument or reconfigurable measurement device. It isnoted that the presented embodiments are for illustration purposes only,and are not intended to limit the type of reconfigurable device used inthe present invention.

FIG. 4A—Reconfigurable Instrument With FPGA and Processor/Memory

FIG. 4A is a block diagram illustrating a device 143A, e.g., aninterface card, configured with a programmable hardware element and aprocessor and memory according to one embodiment. It is noted that FIG.4A is exemplary only, and the interface card or device 143A may havevarious architectures or forms, as desired. For example, the device maybe internal or external to the computer 102, and may be connected to thecomputer through a network, such as the Internet. In variousembodiments, the device illustrated in FIG. 4A may be one of the DAQinterface cards 142 or 143 shown in either of FIG. 2A or 2C, or may bethe image acquisition device 134 shown in FIG. 2A or 2B. However, asnoted above, the programmable hardware may be included on any of thevarious devices shown in FIG. 2A, 2B, or 2C, or on other devices, asdesired. Also, the programmable hardware illustrated in FIG. 4A is anFPGA, but the device may include other types of programmable hardwareinstead or in addition to, such as a Complex Programmable Logic Device(CPLD) or other type of (re)configurable hardware.

As shown in FIG. 4A, the device 143A may include an I/O connector 202which is operable to send/receive signals. In the embodiments of FIGS.2A, 2B, and 2C, the I/O connector 202 presents analog and/or digitalconnections for receiving/providing analog or digital signals. The I/Oconnector 202 may be adapted for coupling to SCXI conditioning logic 124and 126, or may be adapted to be coupled directly to a unit under test130 or process or system 160.

The device 143A may also include data acquisition (DAQ) logic 204. Asshown, the data acquisition logic 204 may comprise analog to digital(A/D) converters, digital to analog (D/A) converters, timer counters(TC) and signal conditioning (SC) logic as shown. The DAQ logic 204 mayprovide the data acquisition functionality of the DAQ card 143. In oneembodiment, the DAQ logic 204 comprises 4 A/D converters, 4 D/Aconverters, 23 digital I/Os, a RTSI connector, and a TIO. This extrahardware is useful for signal processing and motion controlapplications. The programmable hardware element or FPGA 206 can accessthese resources directly, thereby enabling creation of very powerfulmeasurement, DSP and control applications, among others.

The device 143A may include a programmable hardware element 206. In oneembodiment, the programmable hardware 206 comprises a field programmablegate array (FPGA) such as those available from Xilinx, Altera, etc. Theprogrammable hardware element 206 may be coupled to the DAQ logic 204and may also be coupled to the local bus interface 208. Thus a program,e.g., a graphical program such as a National Instruments LabVIEWgraphical program, or a text program, can be created on the computer102, or on another computer in a networked system, and at least aportion of the program can be converted into a hardware implementationform (hardware configuration program) for execution in the FPGA 206. Theportion of the program converted into a hardware implementation form ispreferably a portion which requires fast and/or real-time execution.Note that although only one programmable hardware element (FPGA) 206 isshown, the programmable hardware 206 may include multiple FPGAs (orother programmable hardware elements) as well.

In the embodiment of FIG. 4A, the interface card 143A may furtherinclude a dedicated on-board processor 212 and memory 214. This enablesa portion or all of a program, e.g., a graphical or text program, to becompiled into machine language for storage in the memory 214 andexecution by the processor 212. This may be in addition to a portion ofthe program being converted into a hardware implementation form in theFPGA 206. Thus, in one embodiment, after a program has been created, aportion of the program may be compiled for execution on the embeddedprocessor 212 and executed locally on the interface card 143A via theprocessor 212 and memory 214, and a second portion of the program may betranslated or converted into a hardware configuration program anddeployed to the FPGA 206 for hardware implementation.

As one example, a first portion of a block diagram of a graphicalprogram (that requires real time or fast execution) may be convertedinto a hardware executable format and downloaded to the FPGA 206 forhardware implementation, and a second portion of the block diagram (thatmay not require real time performance) may be stored in the memory 214as program instructions and executed by the processor 212, in either acompiled or interpreted manner. As another example, a portion or all ofthe block diagram portion of the graphical program may be converted intoa hardware executable format and downloaded to the FPGA 206 for hardwareimplementation, and a user interface portion (or front panel portion) ofthe graphical program may be stored in the memory 214 as programinstructions and executed by the processor 212, in either a compiled orinterpreted manner. Thus the portion of the graphical program whichrequires the most real time or deterministic performance may be executeddirectly in hardware for fast operation, and other parts of the blockdiagram, i.e., the user interface portion, which may not require realtime performance, may execute on the processor 212. Where the processorexecutes the user interface portion, the processor may then sendresulting signals to the video subsystem for display of the userinterface on the computer display.

As shown, the device 143A may further include bus interface logic 216and a control/data bus 218. In one embodiment, the interface card 143Ais a PCI bus-compliant interface card adapted for coupling to the PCIbus of the host computer 102, or adapted for coupling to a PXI (PCIextensions for Instrumentation) bus. The bus interface logic 216 and thecontrol/data bus 218 thus present a PCI or PXI interface.

The device 143A may also include local bus interface logic 208. In oneembodiment, the local bus interface logic 208 may present a RTSI (RealTime System Integration) bus for routing timing and trigger signalsbetween the interface card 143A and one or more other devices or cards.

In one embodiment, the device 143A also includes a non-volatile memory288 coupled to the programmable hardware element 206. The non-volatilememory 288 may be operable to store software programs that are to beexecuted by the processor and memory 212 and 214. The non-volatilememory 288 may also be operable to store a hardware configurationprogram (or hardware description) received from the host computer systemto enable configuration or deployment of the hardware configurationprogram in the programmable hardware element 206.

FIG. 4B—Reconfigurable Instrument with FPGA

In the embodiment of FIG. 4B, the processor 212 and memory 214 are notincluded on the device 143B. Thus the device 143B includes aprogrammable hardware element, but does not include a processor ormemory. Thus a task specification or program (or program portion) may beconverted into a hardware configuration program (such as via a netlist)and uploaded to the FPGA 206. Thus in the embodiment of FIG. 4B, anysupervisory control portion of the task or program which is necessary ordesired to execute on a programmable processor in software may beexecuted by the host CPU in the computer system 102, and not executedlocally by a processor on the device 143B. In one embodiment, the device143B may include a non-volatile memory (not shown) coupled to theprogrammable hardware element 206. As described above, the non-volatilememory may be operable to store the hardware configuration programreceived from the host computer system for deployment to theprogrammable hardware element 206, e.g., prior to or during booting ofthe computer system 102.

FIG. 4C—Reconfigurable Instrument with Processor and Memory

In the embodiment of FIG. 4C, the processor 212 and the memory 214 areincluded on the device 143C, but the FPGA 206 is not included. Thus, inthe embodiment of FIG. 4C, a portion of a program, e.g., a portion of ablock diagram of a graphical program, may be stored in the memory 214 asprogram instructions and executed by the processor 212, in either acompiled or interpreted manner. As one example, the memory 214 may storea real time operating system for executing programs. The memory 214 mayalso store a graphical program execution engine for executing graphicalprograms. Thus, as one example, a measurement program that may requirereal time performance may be stored in the memory 214 as programinstructions and executed by the processor 212, under the control of aRTOS, to perform a particular measurement task. In this manner, thedevice 143C may operate as any of a number of measurement instruments,albeit with performance somewhat below what may be possible with an FPGAor other programmable hardware.

FIG. 4D—Smart Sensor with FPGA and Processor/Memory

FIG. 4D illustrates a block diagram of a smart sensor 190. As shown, thesmart sensor 190 may include a programmable hardware element(programmable or reconfigurable hardware) 206 according to an embodimentof the present invention, e.g., an FPGA. The smart sensor 190 may alsoinclude a processor 212 and memory 214.

The programmable hardware element 206 in the smart sensor 190 may beconfigured with a hardware configuration program that implements ameasurement function, e.g., an image processing function. The smartsensor 190 may also comprise a sensor 282 coupled to the programmablehardware element 206. The smart sensor 190 may also include a memory (amemory medium) 214 coupled to the sensor that stores acquired data,e.g., an acquired image. The memory 214 may be designed to store aportion of an image, a whole image, or two or more images. The memory214 may include a memory controller (not shown). If the smart sensor 190includes an analog sensor, the smart sensor 190 may further includeanalog to digital (A/D) logic (not shown) for converting analog signalsinto digital signals, e.g., image signals into a digital image, forstorage in the memory. The smart sensor 190 may also optionally includetimer/counter logic 286 that may perform timing/counting operations,e.g., during operation of the programmable hardware element. The smartsensor 190 may also optionally include a non-volatile memory 288 whichmay be operable to store one or more programs, e.g., software programsor hardware configuration programs, received from the host computersystem.

As noted above, the smart sensor 190 may include a processor 212 (ormultiple processors 212) coupled to memory 214 and the sensor 282. Asdescribed above with reference to FIG. 4A, the processor 212 may beoperable to execute a portion or all of a program that implements ameasurement function. For example, the processor 212 may execute aprogram (which may require real time performance) to interface with thesensor 282 and/or control smart sensor functionality.

In one embodiment, the smart sensor 190 may not include the processor212, but rather may only include the FPGA 206 (or multiple FPGAs) as thefunctional unit. In another embodiment, the smart sensor 190 may notinclude the FPGA 206, but may use just the one or more processors 212for on-board processing. In other embodiments, the smart sensor 190 mayinclude various combinations of both processors and FPGAs to performsmart sensor operations.

In one embodiment, the sensor 282 may comprise a camera, and the smartsensor 190 may comprise a smart camera. The camera may be digital oranalog, and may be operable to generate any of a variety of images,including Infra-Red (IR), visible spectrum, Ultra-Violet (UV), or anyother type of image.

FIG. 5—Method for Configuring a Measurement System

FIG. 5 is a flowchart diagram illustrating one embodiment of a methodfor configuring a measurement system to perform a specified measurementtask. FIGS. 6A-6C are flowcharts which illustrate examples of the methodof FIG. 5. FIGS. 5 and 6A-6C are discussed together below.

The various methods described below include scenarios where the user hasa computer system (“client computer system”) which can interface to anetwork (e.g., the Internet) to access a configuration server. The usermay desire to obtain: 1) configuration data or programs for the clientcomputer system, 2) configuration data or programs for a measurementdevice coupled directly to or comprised in the client computer system(e.g., any of the devices shown in FIGS. 2A and 2B); and/or 3)configuration data or programs for a measurement device that is coupledto a network (e.g., the Internet), where the measurement device is notdirectly coupled to the client computer system, but rather may be aremote measurement device.

In examples 2 and 3 above, the user may desire to configure ameasurement device, such as a smart sensor, expansion card, etc., whichdoes not have its own display capabilities. In example 3 above, the usermay desire to configure a measurement device that is in a differentlocation, such as smart sensors or other embedded devices, e.g., on afactory floor. Thus, in example 3, the user may provide a networklocation, e.g., an IP address, of the measurement device beingconfigured. Thus, the user may be required to use a separate computersystem (the “client computer system”) which has a display in order toimplement the method described herein and configure a measurement devicethat does not inherently include display capabilities.

FIG. 5—Configuring a Measurement System for a Measurement Task

FIG. 5 is a flowchart diagram illustrating one embodiment of a methodfor configuring a measurement system for a measurement task. It is notedthat the flowcharts of FIG. 5 and FIGS. 6A-6C are exemplary only.Further, various steps in the flowcharts of FIG. 5 and FIGS. 6A-6C mayoccur concurrently or in a different order than that shown, or may notbe performed, as desired. Also, various additional steps may beperformed as desired.

Step 502

As shown, in step 502 a measurement system server 103 may be accessed,for example by a client computer system 102 over a network 104, such asthe Internet. In one embodiment, the client computer system 102 mayaccess the server 103 via a web browser, such as Netscape Navigator orMicrosoft's Internet Explorer. In other embodiments, various othersoftware programs may be used to access the server 103. In oneembodiment, the server 103 may host a vendor's web site through whichthe client computer system 102 and/or the user may interface with theserver 103.

In one embodiment, the access of the server 103 may be initiated by auser. In other words, a user may launch a web browser on the clientsystem 102 to access the vendor's web site to purchase a customizablemeasurement product. In another embodiment, the access may be initiatedprogrammatically by software executing on the client computer 102.

Step 504

In step 504 information on a desired measurement task to be performed bythe measurement system (referred to as requirements) may be provided tothe client computer system 102. In step 504 the client computer 102 mayreceive user input indicating the one or more requirements and may thenprovide this user input over a network to the server 103 in step 506. Asused herein, the term “requirements” refers to any of various types ofinformation describing or specifying a task, such as a measurement task.For example, the term “requirements” may include a specification ofnecessary hardware devices for performing the task.

In one embodiment, in step 504 the client computer system 102 maydisplay a graphical user interface (GUI) on its display. The user of theclient computer system 102 may then provide input to the GUI indicatingthe one or more requirements for the measurement task. The GUI maycomprise a plurality of panels which guide a user of the client computersystem 102 in providing the one or more requirements for the measurementtask. The GUI may also comprise menus, dialog boxes, text entry fieldsand/or other similar graphical user interface elements. The GUI may bedisplayed by software executing on the client computer system 102.Alternatively, the server 103 may provide a graphical user interface(GUI) to the client computer system over the network, wherein the clientcomputer system 102 displays the received GUI from the server.

In one embodiment, the user may invoke a measurement task specifier,e.g., running on either the client computer system 102 or the server103, to specify or configure the desired measurement task, therebyproducing a measurement task specification. The measurement taskspecifier may include a graphical user interface (GUI) which enables theuser to easily and simply specify or configure a desired measurementtask. This may involve selecting various parameters of the task such asthe type of measurement being performed using voltage, current, desiredsignal analysis, etc. and other measurement settings and desiredoperation.

In one embodiment, the measurement task specifier may comprise ameasurement task wizard. In other words, the measurement task specifiermay be a software program which leads the user through a measurementtask specification process, thereby generating the measurement taskspecification. In another embodiment, the measurement task specifier maycomprise a measurement task configurator. The measurement taskconfigurator may be a software program invocable by the user under adevelopment environment, such as National Instruments' LabVIEWenvironment, Measurement Studio programming development environment, orany other development environment. In yet another embodiment, themeasurement task specifier may be an API through which the user makescalls to generate the task specification. The measurement task specifiermay thus generate the measurement task specification in response to userinput. For example, in the case that the measurement task specifier isinvoked by the user from the LabVIEW graphical development environment,the user may specify or configure a measurement task by placing or“dropping” nodes or icons on a graphical diagram and connecting thenodes via virtual “wires” to generate a graphical diagram or model ofthe measurement task. The graphical development environment program(e.g., LabVIEW) may generate software objects or data structurescorresponding to the components of the graphical diagram which specifythe measurement task. These data structures may comprise the measurementtask specification.

As another example, consider the case where the measurement taskspecifier is an API in a text-based development environment, such asMicrosoft Corporation's Visual C++ development environment. In thisembodiment, the user may make API function calls in a C++ applicationprogram to specify the various attributes or aspects of the desiredmeasurement task, such as measurement type (voltage, current, pressure,etc.), timing or sampling parameters, or other measurement taskspecification information. The executed functions may producecorresponding data structures which contain specification informationfor the measurement task.

For one embodiment of a measurement task specifier, please seeco-pending U.S. Patent Application Ser. No. 60/301,15 titled“Measurement System Software Architecture for Easily CreatingHigh-Performance Measurement Applications,” filed Jun. 29, 2001, whichwas incorporated by reference above. It is noted that other means ofcommunicating the one or more requirements to the server 103 are alsocontemplated, including FAX, email, telephone, and speech recognition,among others.

As one example of step 504, the user may use a graphical programmingdevelopment environment such as LabVIEW to create a graphical programthat specifies at least part of the desired measurement task. Increating a graphical program, the user may place one or more icons ornodes on the display and connect them in a desired way to accomplish thedesired result. The user may also specify other desired operation. Thegraphical program and other user input may be provided to the server 103and used by the server to generate a more complete program thataccomplishes the user's desired task. Alternatively, the server 103 maygenerate a hardware configuration program based on the graphicalprogram.

In one embodiment, the server 103 (or the client computer 102)automatically creates a configuration diagram based on the user'scurrent measurement system configuration. The configuration diagram mayinclude device icons representing devices present in the user's systemand program icons representing programs present in the user's system.The configuration diagram may be created with the aid of a configurationprogram, such as National Instrument's Measurement and AutomationExplorer (MAX). The server 103 (or the client computer 102) mayprogrammatically or automatically create and display a configurationdiagram as described in U.S. Patent Application Ser. No. 60/312,242titled “System and Method for Graphically Creating, Deploying andExecuting Programs in a Distributed System” filed Aug. 14, 2001, whoseinventors are Jeffrey L. Kodosky, Darshan Shah, and Steven W. Rogers.The client computer system 102 may display the configuration diagram(generated by the client or provided by the server). Where the server103 creates the configuration diagram, the server 103 may download theconfiguration diagram to the client computer system 102, or simplydisplay the diagram on the client system 102, e.g., in the client'sbrowser. Where the client computer 102 (or the user) creates theconfiguration diagram, the configuration diagram may be used to provideinformation to the server 103 about the current configuration of thesystem. The user may also manually create the configuration diagram byselecting and interconnecting device icons. Also, the server 103 orclient 102 may programmatically create a first portion of theconfiguration diagram and the user may manually create a second portionof the configuration diagram.

In one embodiment, the user may then graphically modify or manipulatethe configuration diagram to specify requirements for the desiredsystem. For example, the user may select device icons from a paletteoffered by the server 103. The user can “drag-and-drop” device iconsfrom the server palette onto the user's configuration diagram toindicate that the user would like to purchase these devices. As anotherexample, the user can “drag-and-drop” pre-existing program icons fromthe server palette onto the user's configuration diagram to indicatethat the user would like to purchase these programs. As another example,the user may select device icons in the configuration diagram toinitiate a respective wizard configuration program (either executing onthe client 102 or the server 103) which guides the user in creating aprogram or configuration for the selected device. The user may usevarious other methods to graphically create, modify or manipulate theconfiguration diagram to specify requirements for the desired system.

The user may also use a prototyping environment to specify therequirements for the measurement task. In a prototyping environment theuser may select operations that are recorded in a script or datastructure. In one embodiment of a prototyping environment, the user mayselect the operations by applying the operations to an object, such asan image. An exemplary prototyping environment is the NationalInstruments Vision Builder product. For more information on an exemplaryprototyping environment please see U.S. patent application Ser. No.09/587,682, referenced above.

In another embodiment the user may browse existing configurationdiagrams in a database, and select a configuration diagram thatrepresents, or is close to, the user's desired measurement task. Theexisting configuration diagram may include device icons representingrequired devices and program icons representing programs, among otherinformation. The user may also browse existing graphical programs thatrepresent, or are close to, the user's desired measurement task.

The user may also browse existing solutions based on the requirementsthe user has entered. For example, the server may receive initialrequirements, suggest various solutions, and the user may then selectand optionally further modify the solution. The solution may take theform of one or more of a configuration diagram, graphical program, etc.Then user may then modify the configuration diagram or use a wizardprogram as described above to further specify requirements of the task.

In one embodiment, the user may use combinations of the above methods tospecify the measurement task. For example, in one embodiment, the usermay create a high level configuration diagram and/or graphical programto specify the desired measurement task at a high level, and in additionthe user may also specify desired operation using a wizard-based manner.Creation of the configuration diagram may involve automatic or manualcreation or display of device icons, program icons and interconnectionsthat represent the current system configuration. Creation of the highlevel graphical program may involve selecting and interconnecting asmall number of function icons or nodes, such as a measurement readnode, a measurement analysis node, and/or a measurement write node. Theuser may then use a wizard, e.g., a series of dialog boxes or userinterface panels, to further specify desired operation. As anotherexample, the user may select an existing configuration diagram, provideinput to modify the configuration diagram, and use a wizard-basedprogram to provide further input on desired operation. Various othercombinations of the above methods are possible, as well as othermethods.

The user input (requirements) may include domain specific user input.For example, in a measurement application, the user input may bemeasurement specific user input. The measurement specific user input orrequirements may include, but are not limited to, one or more of ameasurement function (i.e., instrument) type, such as an oscilloscopefunction, multimeter function, DAQ function, machine vision function,image processing function, motion control function, process controlfunction, simulation function, automation function, plant controlfunction, or measurement analysis function; sampling rate; gain;measurement type, such as voltage, resistance, temperature, current,pressure, photonic intensity, frequency, etc.; a component listindicating hardware and/or software components which the user eitheralready has, or which the user wishes to use to perform the measurementfunction; publishing information, such as a URL (Universal ResourceLocator) indicating a target site or device to which products may besent, or the name and/or location of a logging file; constraints, i.e.,metrics which the user may wish to be minimized or maximized (i.e.,optimized), such as cost, weight, performance, form-factor, etc.;platform or bus information, such as MacOS, Unix, Solaris, Windows NT,or PCI, PXI, VXI, USB, Wireless Ethernet (IEEE 802.11), Bluetooth, etc.,which the user may prefer for the measurement system; measurement taskspecifications, such as a script, a task list, menu or buttonselections, drag and drop activity, as in a graphical developmentenvironment; programs; or any other user input which is germane to themeasurement task or system.

In one embodiment, as part of the requirements provided by the user, theuser may specify available (or installed) hardware and/or softwarecomponents of the measurement system, described above. Alternatively,the server 103 may automatically determine available (or installed)hardware and/or software components of the measurement system.

Step 506

In step 506 information on a desired measurement task to be performed bythe measurement system (referred to as requirements) may be provided tothe server 103. Thus the client computer system 102 may provide thereceived information (the requirements) over the network (e.g., theInternet) to the sever 103. In one embodiment, as noted above, theserver 103 may query the client system to determine the various hardwaredevices and/or programs that the user currently has installed in his/hermeasurement system. The server 103 may use this information (theserequirements) in determining hardware and/or programs for themeasurement task in step 508. It is noted that steps 504 and 506 may beconsidered as being performed in one step or as one action.

Step 508

In step 508 the server 103 may determine one or more measurementproducts (e.g., configuration information and/or programs) in responseto the requirements. In one embodiment, determining one or moremeasurement products may comprise analyzing the measurement taskspecification and determining configuration information and/or programsthat will accomplish the measurement task specification. The server mayalso determine one or more proposed solutions, where the term solutionmay include required devices, measurement products (e.g., configurationinformation and/or programs), a configuration diagram, and otherinformation.

The server 103 may analyze the received information (requirements) andmay determine and provide two or more of: configuration information,software program(s), and/or hardware configuration programs, based onthe requirements.

In one embodiment, an expert system comprised on the server 103 mayoperate to analyze the measurement task specification and determine theone or more measurement programs and/or measurement device products. Theexpert system may also validate the measurement task specification,i.e., may determine if the specified measurement task may be implementedwith available resources. In one embodiment, determining the one or moremeasurement device products may comprise creating a runtimespecification based on the measurement task specification. The runtimespecification preferably comprises parameter settings for one or moremeasurement devices and other hardware comprised within the system, andmay also specify software components or software programs which are tobe used during execution of the task. In one embodiment, the runtimespecification may comprise a specification of the parameters of one ormore measurement primitives, where each measurement primitive comprisesa software object and corresponding configuration settings, and whereeach measurement primitive is operable to implement at least a portionof the measurement task.

In one embodiment, the expert system may comprise a plurality of expertswhere one or more expert programs are available for each of varioustypes of application or problem domains. Said another way, one or moreexperts may exist for each of various types of measurement tasks orsub-tasks. Thus, depending upon the type of measurement task specifiedor configured by the user in step 504, one or more corresponding expertsthat correspond to the problem domain of the task may be invoked tocreate the runtime specification.

As mentioned above, in one embodiment, the measurement system maycomprise the client computer system and one or more measurement devicescoupled to or comprised in the computer system. The one or moremeasurement products may comprise configuration information which isoperable to configure one or more of the client computer system and theone or more measurement devices to perform the measurement task. Theclient computer system 102 may include a configuration software program(such as National Instrument's MAX) which is operable to receive theconfiguration data and configure the measurement system (one or more ofthe client computer system 102, the one or more measurement devices).Alternatively, the product may comprise configuration data and aninstaller, wherein the installer is executable by the client computersystem 102 to configure the measurement system using the configurationdata. As another alternative, the product may include configuration dataand configuration software which is executable by the client computersystem 102 to configure the measurement system, and one or moreapplication programs with the configuration data.

In another embodiment, the one or more measurement products may includesoftware programs (application software and/or drivers) which areexecutable by the measurement system (by the client computer system 102and/or the one or more measurement devices) to perform the measurementtask. For example, in one embodiment, the downloaded software productmay include one or more of a graphical program or machine executablecode which is executable to perform the measurement task. In anotherembodiment, the application software may include text based source codewhich is compilable and executable, or interpretable, by the clientcomputer system to perform the measurement task using the one or moremeasurement devices.

As another example, the downloaded software product may comprise aself-executing program file which may operate to configure one or bothof the client computer system 102 and the one or more measurementdevices with configuration information or with other software program. Ameasurement device (which may also be called a reconfigurableinstrument) may comprise a processor (CPU) and a memory (or multipleprocessor/memory elements), for executing a received software program.

As mentioned above, in one embodiment at least one of the measurementdevices may comprise a programmable hardware element, such as an FPGA.In this case, the product may include one or more hardware configurationprograms (hardware descriptions or netlists) which are usable toconfigure the programmable hardware element. The downloaded hardwareconfiguration program may be usable to configure the programmablehardware element, e.g., one or more FPGAs, to perform the measurementtask.

In one embodiment, in step 508 the server 103 may also determinerequired hardware and/or devices for the measurement task. In otherwords, the server 103 may determine one or more measurement deviceproducts in response to the one or more requirements. In one embodiment,determining one or more measurement device products may compriseanalyzing the measurement task specification and determining hardwarewith which to implement the measurement task. This embodiment isdescribed further with respect to FIG. 10.

Step 510

In step 510 the server 103 may provide or download products (programsand/or configuration information) for the measurement task to the clientcomputer system 102. Said another way, the server 103 may provide one ormore measurement program products or configuration information to theclient computer system 102 which are usable to configure the measurementsystem to perform the measurement task. The measurement system may beoperable to be configured to perform the measurement task after receiptof the measurement program products and/or configuration information.Further user development may also be necessary to complete the receivedprograms.

In one embodiment, the server 103 may provide the one or moremeasurement programs over the network, such as the Internet, to theclient computer system 102. Thus the one or more measurement programsmay be configured as IP packets and transferred over the Internet to theclient computer system 102.

In one embodiment, the server 103 provides software products to theclient computer system 102 in the form of a Compact Disc (CD) which maybe delivered by mail to the user for installation on the client computersystem 102. Other media may also be used to transfer the one or moremeasurement software products, including tapes, discs, or any othersuitable medium. In another embodiment, the one or more measurementsoftware products may be provided to the client system by sending theclient system (or the user) a key or password which may be used todownload the measurement software products from a website or othermedium.

In one embodiment, prior to (or after) downloading, the server 103 maysend data and information to the client computer system 102, e.g., usingdynamic web page generation technology, to visually depict current orfinal ‘as purchased’ customized products (i.e., the one or moremeasurement products customized for the user's measurement task). Forexample, the server 103 may cause to be displayed a configurationdiagram illustrating the proposed or “as-purchased” products. The usermay verify the visually depicted customized products for accuracy,completeness, etc. prior to proceeding with payment and final check out.

In one embodiment, the client computer system 102 may provide a digitalcertificate to the server 103 for security, i.e., to verify the identityof the client computer system 102 and/or the user before providing themeasurement software products. In another embodiment, a digitalcertificate may be provided by the server 103 to the client system toverify that the measurement software products being provided are in factthe correct products for the specified measurement task or measurementsystem.

In one embodiment, the server 103 may receive payment information to payfor receipt of the products. For example, the client computer system 102may provide payment information to pay for receipt of the products. Thepayment information may also be provided to a separate e-commerceserver.

Step 512

In step 512, the provided products may be installed or configured on theclient computer system 102 and/or a measurement device. Note that invarious embodiments, the installation and/or configuration may beperformed by the user, by software executing on the client computersystem 102, or by software executing on the server 103.

Where the received product is configuration information, step 512 maycomprise the measurement system executing a configuration program toconfigure various components in the measurement system (includingsoftware and devices) according to the configuration information. Thismay involve setting various hardware parameters, setting softwareparameters, etc. A configuration program, such as National Instrument'sMAX, may configure various components using the configurationinformation.

Where the received product is one or more software programs, step 512may comprise storing the software programs in a memory medium of thetarget device (the client computer system or a measurement device) forexecution by a processor.

Where the received product is a hardware configuration program, step 510may comprise configuring a programmable hardware element in themeasurement system with the hardware configuration program.

Step 514

After the products provided by the server 103 have been configuredand/or installed on the measurement system (on the client computersystem and/or a device), in step 514 the measurement system may executeto perform the measurement function. Where the received product isconfiguration information, this may comprise the measurement systemexecuting according to the configuration information. Where the receivedproduct is one or more software programs, the measurement system mayexecute the one or more software programs in performing the measurementtask. Where the received product is a hardware configuration program, aprogrammable hardware element in the measurement system may operateaccording to the hardware configuration program. Various combinations ofthe above may also occur.

When the measurement system executes to perform the measurementfunction, the measurement system may operate to acquire a signal from asignal source and analyze the signal after the acquisition. The signalsource may be a unit under test (UUT), a sensor, or other signal source.

In some embodiments, the received programs may be incomplete orinsufficient to fully perform the user's desired task. In this case, theuser may be prompted for more information or requirements.Alternatively, the user may be expected to complete or finish a receivedprogram in some way. In one embodiment, the server 103 may also provideone or more development tools, or the development tools may be madeavailable on the server in an ASP (application service provider) model.The user may then use these tools to further complete a received programor product.

FIGS. 6A-6C—Exemplary Embodiments of FIG. 5

FIGS. 6A-6C illustrate exemplary embodiments of FIG. 5.

As shown in FIG. 6A, the server 103 may determine (e.g., generate)configuration information for the task in step 508A. As shown in FIG. 7,in one embodiment in step 602 the server 103 may analyze the receivedinformation (requirements) and in step 604 may determine parametersetting values and/or other configuration data based on therequirements. The server 103 may produce a configuration file that canbe used to configure devices or software present in the measurementsystem. For example, the server 103 may generate a configuration filethat can be used by a configuration program resident in the clientcomputer system. One example of a configuration program targeted formeasurement (including automation) is Measurement and AutomationExplorer (MAX) offered by National Instruments Corporation. In step 512Athe client computer system, e.g., the configuration program, may deploythe configuration information to the respective devices.

FIG. 6B illustrates an embodiment of FIG. 5 where the server 103generates software programs for the task. As shown in FIG. 6B, theserver 103 may determine (e.g., generate) software programs for thetask. As shown in FIGS. 8A and 8B, in one embodiment in step 602 theserver 103 may analyze the received information (requirements) and maydetermine one or more software programs based on the requirements. Forexample, in step 612 of FIG. 8A the server 103 may retrieve pre-existingsoftware program(s) from a memory medium or database based on therequirements. In step 614 of FIG. 8B the server 103 may automatically orprogrammatically generate software program(s) (e.g., a graphicalprogram) based on the requirements. The server may also perform acombination of steps 612 and 614, e.g., retrieve some pre-existingprograms and programmatically generate others.

Where the server 103 determines or generates one or more softwareprogram(s), the software program(s) may include executable code which isexecutable by the measurement system to perform the measurement task.The software program(s) may also include source code which is one ormore of: 1) compilable and executable, or 2) interpretable, by themeasurement system to perform the measurement task. The softwareprogram(s) may also include at least one graphical program.

The generated software program(s) may be targeted for execution by theclient computer system 102 and/or a measurement device coupled to orcomprised in the client computer system 102. The generated softwareprogram(s) may also be targeted for execution by a remote device.

Where the generated software program is a graphical program, themeasurement system (either the computer system or a device) may includea graphical program execution engine for executing the graphical programto perform the measurement task. For example, the server 103 maygenerate a LabVIEW graphical program, and the measurement system mayinclude a device executing LabVIEW RT which executes the LabVIEWprogram. The software program(s) may take other forms, such as scripts,etc.

Various methods for receiving user requirements and generating asoftware program in response thereto are described in the followingpatent applications, referenced above and incorporated herein byreference.

U.S. patent application Ser. No. 09/745,023 titled “System and Methodfor Programmatically Generating a Graphical Program in Response toProgram Information,” filed Dec. 20, 2000.

U.S. Patent Application Ser. No. 60/301,15 titled “Measurement SystemSoftware Architecture for Easily Creating High-Performance MeasurementApplications,” filed Jun. 29, 2001.

U.S. patent application Ser. No. 10/008,792 titled “Measurement SystemSoftware Architecture for Easily Creating High-Performance MeasurementApplications,” filed Nov. 13, 2001.

The software programs may then be downloaded and deployed in steps 510Band 512B, respectively.

FIG. 6C illustrates an embodiment of FIG. 5 where the server generatesat least one hardware configuration program. In one embodiment, asdiscussed above, in steps 504 and 506 the user may input a specificationor requirements for the desired task (e.g., measurement task) to theserver 103, and in 508C the server 103 may determine, e.g., generate, ahardware configuration program based on this information. The server 103may select a pre-compiled hardware configuration program, or mayprogrammatically generate a new hardware configuration program.

In one embodiment, in steps 504 and 506 the server 103 may present aconfiguration tool on the client computer 102 specifically designed forcreating a hardware configuration program. For example, theconfiguration tool may comprise one or more programs implementing aconfiguration wizard. The wizard may be operable to lead a user throughthe configuration process, receiving user input specifying the userrequirements for the system, providing various information specific tothe hardware configuration program generation process, and generating ahardware configuration program for deployment on a programmable hardwareelement in the client system, e.g., a RIO (reconfigurable I/O) device inthe client system. A RIO device is a device that includes a programmablehardware element and fixed hardware resources. In one embodiment, theconfiguration tool (e.g., the wizard) may also be operable to deploy thehardware configuration program onto the programmable hardware element inthe client system, e.g., the RIO device.

As discussed generally above, a vendor may operate or host theconfiguration wizard on server computer system 103, such as ane-commerce server, which may be accessible to users (i.e., customers)over a network, e.g., the Internet. The client computer system 102 maybe coupled to the server computer system 103 over the network, such asthe Internet. The configuration wizard program may be stored andexecuted on the server computer 103. Software executing on the clientcomputer system (e.g., a browser program) may be used to access theserver (i.e., the configuration wizard). The user may thereby engage theconfiguration wizard remotely to specify a configuration of the desiredtask, and to download or deploy the resulting hardware configurationprogram generated by the configuration wizard onto a programmablehardware element (e.g., a RIO device). In one embodiment, the vendorserver may provide sales and purchasing services to the customer inaddition to system configuration.

Thus the server program (configuration wizard) may present a graphicaluser interface (GUI) to the user on the client computer system 102 andreceive input therefrom specifying user requirements for the system tobe configured. Where the GUI is targeted to hardware configurationprograms, the GUI may provide one or more different approaches orsupport levels for performing the customization, each targeting adifferent class of users. For example, a basic support level may includeproviding precompiled hardware configurations from which the user mayselect a solution. This approach offers the least flexibility, butsimplifies the choices that the user may consider. This approach may inmany ways be considered a parameterized solution, in that thepre-defined nature of the hardware resources is very structured, withwell defined acquisition modes and functionality.

In contrast, another embodiment of the configuration process offers verylittle pre-defined structure. This embodiment may mix program primitives(e.g., LabVIEW primitives) with low level I/O, and allows for theconstruction of timing, triggering, inline processing, and more. Thesebuilding blocks can be pieced together to create the same functionalityas the existing solutions, as well as much more capable operations.These blocks can often be combined in different ways to provide similarsolutions, but one may be preferable to the other in terms ofextensibility, resource utilization, etc. This approach offers thegreatest flexibility, but requires a more sophisticated user.

In one embodiment, as mentioned above, the configuration wizard mayprovide a drag and drop interface for creating the user definedconfiguration. In another embodiment, the wizard may provide a menuand/or button based graphical interface for creating the user definedconfiguration. In another embodiment, the wizard may provide a list ofavailable resources, e.g., low level interface primitives such as AI,AO, and DIO, as well as a list of higher level functions that can beapplied to these low-level primitives, including higher level interfacefunctions such as counters built on top of DIO lines, or inlineprocessing such as linearization or filtering for AI lines. Theconfiguration wizard may include or utilize a graphical programdevelopment environment such as LabVIEW.

The user may select the resources required by an application, andconfigure any resources as necessary (for example, setting gainparameters on an analog input resource) using the configuration wizard.In one embodiment, the selections may be hierarchical, and may allow theuser to add the higher level interface or inline processing in the samewindow. The user may then identify the timing and triggeringrequirements of the application, selecting from the resourcesidentified/created in the previous step.

In one embodiment a description file may be generated which identifiesresources and features the task requires or that the user has selected.From this description file, G code (graphical code, e.g., NationalInstruments G graphical programming language) may be generated. HDL codemay then be generated from the G code (or directly from the descriptionfile), and eventually a program binary file, i.e., a hardwareconfiguration program, for the FPGA generated from the HDL code. Inthese approaches, caching schemes may be used so that the number ofcompilations may be minimized.

In step 508C the server 103 may determine at least one hardwareconfiguration program based on the requirements the user has provided.As shown in FIGS. 8A and 8B, in one embodiment in step 602 the server103 may analyze the received information (requirements) and maydetermine one or more hardware configuration programs based on therequirements. For example, in step 612 of FIG. 8A the server 103 mayretrieve pre-existing hardware configuration program(s) from a memorymedium or database based on the requirements. In step 614 of FIG. 8B theserver 103 may automatically or programmatically generate hardwareconfiguration program(s) based on the requirements. The server may alsoperform a combination of steps 612 and 614, e.g., retrieve somepre-existing hardware configuration programs and programmaticallygenerate others.

In one embodiment, specific features (as opposed to completeconfigurations) may be pre-compiled in such a way that they may beassembled or composed quickly into an appropriate configuration. Theadvantage of this approach is that most of the relative placement androuting has been done up front, and so only a “quick” replacement andrerouting is needed to put the configuration together. In anotherembodiment of this approach, a set or library of complete configurationsmay be maintained by the server 103 (or a separate computer) and madeavailable for a wide variety of applications. The server (or user) mayselect a best solution (i.e., configuration), then make modifications asneeded.

In one embodiment, the server 103 may maintain a cache for storing oneor more pre-compiled portions of the program, so that successivecompiles may be performed more quickly than the original compilation. Inother words, in one embodiment, incremental compilation may besupported. In another embodiment, the server 103 may support a graphicalprogram differencing or “diff” method for detecting changes in graphicalprograms. An example of a graphical program “diff” application isdescribed in U.S. Pat. Nos. 5,974,254 and 6,138,270, which areincorporated herein by reference as though fully and completely setforth herein. The graphical program diff method may detect differencesin two graphical programs (e.g., successive versions of the samegraphical program), and only the differences may need to be compiled.

In addition, the server 103 may search pre-existing hardwareconfiguration programs in a database to attempt to find an existinghardware configuration program that satisfies the user's requirements.The server 103 may offer an existing hardware configuration program thatincludes more functionality than the user's task requires. The user canchoose to accept this pre-existing program, trading off the drawback ofa larger footprint for no required compile time.

Various methods for receiving user requirements and generating ahardware configuration program in response thereto are described in U.S.patent application Ser. No. 10/058,150 titled “ReconfigurableMeasurement System Utilizing a Programmable Hardware Element and FixedHardware Resources”, filed on Oct. 29, 2001, referenced above andincorporated herein by reference.

Thus, in one embodiment, the server 103 may analyze the receivedinformation (requirements) and may determine one or more hardwareconfiguration programs based on the requirements. The server 103 mayretrieve pre-existing hardware configuration program(s), mayautomatically or programmatically generate hardware configurationprogram(s), or a combination thereof.

As discussed above, where the server 103 determines or generates ahardware configuration program, the server 103 may programmaticallygenerate the hardware configuration program directly from the receivedrequirements. Alternatively, as shown in FIG. 9A, the server mayprogrammatically generate a software program or other intermediatedescription or data structure based on the requirements in 642, and thenprogrammatically generate a hardware configuration program based on thesoftware program, description, or data structure in 644. As shown inFIG. 9B, the server may programmatically generate a graphical programbased on the requirements in 642A, and then programmatically generate ahardware configuration program based on the graphical program in 644A.

FIG. 8A

FIG. 8A illustrates an embodiment of Step 508 of FIG. 5. In step 602 theserver 103 may analyze the received information (requirements) and maydetermine one or more programs based on the requirements. For example,in step 612 of FIG. 8A the server 103 may retrieve pre-existingprogram(s) from a memory medium or database based on the requirements.The program(s) may be software program(s) or hardware configurationprogram(s).

FIG. 8B

As shown in FIG. 8B and discussed above, in one embodiment the server103 may analyze the received information (requirements) and mayprogrammatically generate one or more programs based on therequirements. In this embodiment, the program(s) that accomplish aportion or all of the measurement task are programmatically orautomatically generated (generated by software). This may involveprogrammatically generating one or more software programs or one or morehardware configuration programs. For example, software executing on theserver 103 may programmatically generate a graphical program, such as aLabVIEW graphical program, based on the requirements. This may involveprogrammatically generating and displaying function nodes or icons andinterconnections among the nodes to specify the graphical program, aswell as the underlying data structures which represent the graphicalprogram. Software executing on the server 103 may also programmaticallygenerate a hardware configuration program based on the requirements.

Configuration Diagram

In one embodiment, the system may display visual information to thecustomer illustrating the product(s) and/or configurations specified bythe customer. In other words, the customer may dynamically be presentedwith a display or picture of the system and/or configuration (e.g., aconfiguration diagram) in or near real time, thereby providing a ‘WhatYou See Is What You Get’ (WSYIWYG) purchasing experience for thecustomer. An exemplary configuration diagram is described below withrespect to FIG. 14.

In one embodiment, the server 103 (or the client computer 102) creates aconfiguration diagram based on the user's measurement system. The server103 (or the client computer 102) may create and display a configurationdiagram as described in U.S. Patent Application Ser. No. 60/312,242titled “System and Method for Graphically Creating, Deploying andExecuting Programs in a Distributed System” filed Aug. 14, 2001, whoseinventors are Jeffrey L. Kodosky, Darshan Shah, and Steven W. Rogers.The client computer system 102 may display the configuration diagram(generated by the client or provided by the server). Where the server103 creates the configuration diagram, the server 103 may download theconfiguration diagram to the client computer system 102, or simplydisplay the diagram on the client system 102.

The configuration diagram may comprise device icons which correspond todevices present in the measurement system. The configuration diagram mayfurther comprise connections displayed between device icons to visuallyindicate physical or logical connections between devices. Theconfiguration diagram may further comprise program icons correspondingto programs present in the measurement system. The program icons may belocated proximate to device icons corresponding to devices on which therespective programs are stored or, in the case of an FPGA, configured.The configuration diagram may also display other information.

The server 103 may create the configuration diagram to document or allowvisualization of the existing measurement system as detected and/orconfigured by the server 103. Also, the user may use the configurationdiagram to deploy received products (e.g., received programs) on variousdevices. For example, once the server 103 generates products for themeasurement system, corresponding icons (e.g., program icons orconfiguration information icons) may appear on the configurationdiagram, such as in a palette. The user may then associate (e.g., dragand drop) these icons to various device icons to configure the system.

In one embodiment, the client computer system 102 may display theconfiguration diagram representing the measurement system as it existsbefore any products are received from the server 103. Where the serverautomatically deploys products to devices in the client system, whenproducts (configuration information and/or programs) are received fromthe server 103, the configuration diagram may be updated accordingly toshow the user how the system has changed. In one embodiment, theconfiguration diagram may show the changes (or deployments) to theclient system in an “animated” fashion, allowing the user to easily seewhat products are being deployed to which devices. For example, programicons may move on the screen to the device icon corresponding to thedevice to which the underlying programs are being deployed. Thisprovides the user with the ability to see how his/her system is beingchanged. The configuration diagram may also be used to show proposedchanges to the measurement system, possibly in an animated fashion, withthe user having the ability to accept or reject the products or changes.

The server 103 may thus animate a configuration diagram displayed on theclient system to visually illustrate to the user how the server 103 ismodifying (or proposing to modify) the client measurement system andprograms. Thus, when the server 103 deploys programs on devices, theconfiguration diagram displayed on the client system may be animatedaccordingly to visually indicate the deployment. For example, a programicon may move on the screen from a server icon representing the serverto the appropriate device icon to visually indicate that the program isbeing deployed on a respective device.

In one embodiment, the user may not be in possession of the requiredmeasurement devices to perform the task. In this case, as discussedbelow with respect to FIG. 10, a manufacturer (the vendor) may beprovided information on the required hardware devices which the vendormay then ship to the user. The vendor may also receive configurationinformation and/or programs and use this to configure the device(s). Theconfigured devices(s) may then be sent to the user to perform themeasurement task.

The configuration diagram may also be modified to display a device icon,possibly with a modified appearance (referred to as a “virtual deviceicon”), corresponding to a hardware device that is not currently presentin the system, but is being shipped to the user. The user may then beable to select the device icon to view product specifications and/orenter ordering information for the product. The user may deploy receivedconfiguration information and/or programs to this non-present or“virtual device” by associating icons (e.g., program icons orconfiguration information icons) to this “virtual device icon”. Theserver 103 may also show an animation of program icons and/orconfiguration information icons being automatically deployed to thisvirtual device icon. When the actual device is received and coupled tothe system, the corresponding programs or configuration information maybe automatically or manually deployed to the device at that time.

FIG. 10—Flowchart of a Method for Configuring a Measurement SystemComprising Reconfigurable Hardware

FIG. 10 is a flowchart of one embodiment of a method for onlineconfiguration of a measurement system, where the measurement system maynot already have the necessary devices or hardware component(s) toperform the desired measurement task. It is noted that the flowchart ofFIG. 10 is exemplary only, and that various steps in the flowchart ofFIG. 10 may occur concurrently or in different orders than that shown,or may not be performed, as desired. Also, various additional steps maybe performed as desired.

As FIG. 10 shows, in 702 a user may enter one or more requirements for ameasurement task. The requirements may be any of various types asdescribed above. Step 702 corresponds to steps 502 and 504 of FIG. 5.

In 704 a database may be queried by the server 103 for hardware devicesthat meet the user requirements for the measurement task. As notedabove, the server 103 may comprise more than one server computer and/orstorage media, and in various embodiments the database may be comprisedon any of the server computers or storage media, and may even bedistributed among multiple computers or storage media.

As described above in step 508 of FIG. 5, in one embodiment, an expertsystem may be used to determine the hardware devices that meet the userrequirements, where the expert system may analyze the user requirements,e.g., the measurement task specification, and determine the appropriatehardware devices and corresponding software and/or parameters needed toperform the specified measurement task.

In 706 products (programs and/or configuration data) needed to configurethe measurement system to perform the specified measurement task may beobtained or determined. In other words, the server 103 may retrieveand/or generate products (programs and/or configuration data) forconfiguring the existing or determined hardware, and possibly othercomponents of the measurement system, including the client computersystem 102. Step 700 corresponds to step 508 of FIG. 5.

In 708 the server 103 may determine whether the user has device(s)(e.g., reconfigurable hardware) which are necessary to perform thedesired task. As one example, the server 103 may determine if the clientsystem has devices operable to be configured with the programs and/orthe configuration data determined in 706. The server 103 mayprogrammatically determine the devices in the client system, or the user(or client system) may provide this information.

If the user does not already have the necessary measurement devices orreconfigurable hardware, then in 712 the server 103 may provideinformation and/or a quote to the user indicating the device(s), or asuggestion of proposed devices, and their prices. The user may thenselect the desired devices and elect to purchase these devices. In 712the hardware specifications for the devices or reconfigurable hardwaremay be sent to a manufacturing system or operation.

In one embodiment, the server 103 may illustrate the proposed device(s)in a configuration diagram, enabling the user to graphically see hisproposed system configuration iconically. Thus the user's existingsystem may be displayed iconically, with device icons representingdevices currently present in the system, and additional device icons maybe displayed representing devices that are recommended for purchase bythe user. The device icons for recommended devices may be have aslightly different appearance (e.g., highlighted in some fashion) tovisually indicate that these correspond to the recommended devices.

When the user elects to purchase or receive a hardware device, a virtualdevice icon may appears on the configuration diagram representing thepurchased device. For example, the virtual device icon may be “grayedout” or otherwise have an appearance indicating that the device is notphysically present. The virtual device icon may change appearance (toappear like a normal device icon) when the physical device is receivedand is detected as being coupled to the system.

In 714, the manufacturer may then provide (ship) the specified hardwareto the user. In 722 the products (configuration information and/orprograms) may be provided to the client system. In 724 the receivedhardware (and/or existing hardware) may be configured with the receivedproducts. In 724 the products (configuration data and/or programs) maybe manually or automatically deployed on the devices, either by themanufacturer prior to shipment, or by either the client computer system102 or the server computer system 103 after shipment and receipt.

In one embodiment, the manufacturer may configure the device(s) orreconfigurable hardware with various products (e.g., configurationinformation and/or programs) to perform the specified measurement taskbefore providing the device(s) to the user. Thus the hardware devicesmay be shipped to the user pre-configured to perform the measurementtask. The hardware devices may also be shipped to the userpre-configured with various appropriate development tools for creatingprograms that perform the desired measurement task.

In another embodiment, in 714 the hardware device(s) may be provided tothe user un-configured. In this embodiment, in 722 the products(configuration information and/or programs) may be providedelectronically to the client system over the network (the Internet).Thus, where the hardware devices are provided to the user un-configuredin 714, in 722 products (configuration data and/or programs) determinedin 706 may be provided to the user. In various embodiments, in 722 theserver 103 may download the configuration data and/or programs over thenetwork to the client computer system 102. The products may also be sentin another fashion, e.g., by sending a physical copy of the data and/orsoftware to the user, e.g., in the form of one or more CDs, tapes,discs, or other media, or by any other means of data transferal. Asdescribed above, the products may comprise any of various types ofconfiguration data and/or programs described above.

Where the hardware devices are provided to the user un-configured in714, the client computer system 102 (or the user) may then beresponsible for configuring the hardware for the measurement task. Asone example, a configuration program resident on the client computersystem may automatically configure received devices for the measurementtask when the devices are detected as being installed in the system.Thus, in one embodiment, configuration information and/or programsreceived from the server 103 over the network may be temporarily storedin the client computer system until the appropriate hardware is receivedand coupled to the system. When the required hardware device(s) aredetected as being received and coupled to the system, the configurationinformation and/or programs may be automatically installed or deployedat that time. For example, programs may be transferred to the client andregistered with a configuration program, such as National Instrument'sMAX. When the hardware device is received and coupled to the system,Plug & Play software detects the device, informs the configurationsoftware program, and the programs are automatically deployed on thehardware device at that time. The deployment of configurationinformation and/or programs may be animated on a configuration diagramshown on the client to visually illustrate to the user how the system ischanging.

In another embodiment, where the hardware devices are provided to theuser un-configured in 714, the server computer system 103 may beresponsible for configuring the hardware for the measurement task. Inthis embodiment, any products determined by the server 103 may remainstored on the server 103 until the hardware devices are received andinstalled on the client computer system 102. The client computer system102 may notify the server when the devices are received and installed.This notification may be automatically performed, e.g., by aconfiguration program executing on the client computer system 102detecting these devices and notifying the server 103. This notificationmay also be manually by the user logging on to the server 103 andproviding user input that the devices are installed. The server 103 maythen at that time download and deploy the products (configurationinformation and/or programs) to the installed devices.

Thus, any of various combinations of programs, software and/or data maybe provided by the server 103 to the client computer system 102 and/orthe user for configuring the measurement system to perform the specifiedmeasurement task. As mentioned in 510 above (with reference to FIG. 5),digital certificates may be used by one or both of the server 103 andthe client computer system 102 to verify the identity of the otherbefore providing the software and/or data. Payment information may alsobe provided to pay for received devices or products.

Thus it is noted that the hardware of the measurement system may beconfigured in any of a number of ways, including manual configuration bythe user, pre-configuration (by the manufacturer, as indicated in 552and 556 above), and programmatic installation and configuration, amongothers. If the devices are provided by or shipped by a manufacturer insteps 712 and 714, then the products (configuration data and/orprograms) may be manually or automatically deployed on the devices priorto shipment, or when the devices are received and installed in thesystem.

Thus, in accordance with the method presented above, a user may specifya measurement task, and configuration software and/or data may beprovided to configure the user's measurement system to perform thespecified measurement task. In addition, if the user does not have thenecessary hardware needed to perform the measurement task, the methodmay provide the requisite hardware (possibly pre-configured to performthe task) to the user. In other words, the user may purchase thehardware from the vendor, who may then deliver the hardware to the user.

FIG. 11—Flowchart of a Method for Configuring a Measurement System Usinga Graphical Program

FIG. 11 is a flowchart of one embodiment of a method for configuring ameasurement system using a graphical program, where the measurementsystem comprises the client computer system 102 and one or moremeasurement devices. In particular, the method describes theconfiguration of a measurement system comprising any of a variety ofmeasurement hardware, including reconfigurable hardware such as FPGAsand/or processor/memory based elements, as well as other measurementdevices comprised in the measurement system. Note that the flowchart ofFIG. 11 is exemplary only, and that various steps in the flowchart ofFIG. 11 may occur concurrently or in different order than that shown, ormay not be performed, as desired. Also, various additional steps may beperformed as desired.

As FIG. 11 shows, in 582 a user may specify a task, e.g., a measurementtask, by specifying one or more of task requirements, application type,and client computer type, among others. For example, parameters such asthe type of measurement being performed, e.g., voltage, current,temperature, etc., and other measurement settings may be indicated. Asdescribed above with reference to FIG. 5, steps 504 and 506, in variousembodiments, the user specifying the task may include the user providinginput to a client computer system 102, accessing a server 103 over anetwork, and providing the task specifications to the server 103 usingany of a variety of means, including a measurement task specifier (alsodescribed above), a FAX, email, telephone, or any other means forcommunicating requirements information to the server 103. In oneembodiment, a measurement task specification specifying the measurementtask may be produced in response to the user provided taskspecifications, preferably by the measurement task specifier.

In 584 a graphical program may be generated which is usable to performthe specified task. The terms “graphical program” and “block diagram”were described above. In one embodiment, the graphical programmingenvironment is comprised on the server 103. In one embodiment, themeasurement task specifier may be comprised in, or may utilize, thegraphical programming environment, and may be operable to generate thegraphical program in response to the user-provided task specifications.

In 586 the graphical program may be sent to the client, i.e., the clientcomputer system 102 and/or the user. As mentioned above, sending thegraphical program to the client may include downloading the graphicalprogram over the network to the client computer system 102, sending aphysical copy of the graphical program to the user, e.g., in the form ofone or more CDs, tapes, discs, or other media, or sending the graphicalprogram to the client by any other means of data transferal. Asmentioned above, digital certificates may be used by one or both of theserver 103 and the client computer system 102 to verify the identity ofthe other before sending the graphical program to the client.

In one embodiment, the client may run or execute the graphical programwith a graphical program execution engine to perform the specified task,as indicated in 588. In other words, the measurement system may includethe graphical program execution engine, thereby facilitating nativeexecution of the graphical program on the system to perform the task.Note that the graphical program execution engine may be comprised on theclient computer system 102, or one or more of the measurement devices.

In another embodiment, the graphical program may be converted to aprogramming language and/or machine code, as indicated in 590. Then, in592, the converted program may be run or executed under an operatingsystem, such as a real time operating system, to perform the task. Inother words, the graphical program may be converted to a ‘lower level’text based programming language such as C, C++, FORTRAN, Basic, Java,etc., then compiled or interpreted for execution under the real timeoperating system, e.g., Microsoft Windows, Sun Solaris, Unix, Linux,etc., or converted to machine code which may be directly executableunder such an operating system without the need to compile or interpretthe converted program.

In yet another embodiment, the graphical program may be converted to oneor more hardware configuration programs (hardware descriptions and/ornetlists), as indicated in 594. In this embodiment the client computersystem 102 and/or one or more of the measurement devices comprisesreconfigurable hardware, such as an FPGA (or multiple FPGAs). Thegraphical program may be converted to a hardware configuration programby the server 103 or by the client system 102. Then in 596 the convertedprogram may be loaded onto the FPGA (or multiple FPGAs), therebyconfiguring the FPGA(s) to perform the task. Then, in 598 the configuredFPGA(s) may operate to perform the task.

Thus, by performing the method described above, a user may specify atask, such as over a network, a server may generate a graphical programfrom the user-specified task specification and send the graphicalprogram to the client, then the client may, if necessary, convert thegraphical program to an executable form. The executable program may thenbe run by the measurement system to perform the specified task. Asdiscussed above, the delivery of the program to the client may occur aspart of an e-commerce transaction between the client or user and thevendor, i.e., a purchase of the product by the client from the vendor.

FIGS. 12A and 12B—Measurement Driver Program Components and Products

FIGS. 12A and 12B illustrate two embodiments of a measurement taskspecification program and related products produced and used by themeasurement task specification program. The measurement taskspecification program may also be referred to as the measurement driverprogram. Note that these embodiments of the measurement taskspecification program include a measurement task specifier and expertsystem, as described above. It should also be noted that theseembodiments are meant to be illustrative of approaches for implementingthe methods described above, and are not meant to preclude otherpossible implementations.

FIG. 12A—Measurement Task Specification Program Components

FIG. 12A illustrates various software components or programs 800Acomprised in the measurement task specification program, also referredto as the measurement driver program. As shown, the measurement taskspecification program may include a measurement task specifier 810, anexpert system 820A with one or more experts 822B, a runtime builder 830,and various measurement primitives 840. The measurement taskspecification program may also include other software components aswell.

As FIG. 12A also illustrates, various of the measurement taskspecification program components may be operable to generate respectiveproducts 850A which may be useable by other measurement driver programcomponents, by other software programs or systems, or by a user. Morespecifically, as shown in FIG. 12B, in one embodiment, the measurementtask specifier 810 may be operable to generate a measurement taskspecification 860 which, as described above, may particularly describethe measurement task specified or configured by the user. In oneembodiment, the measurement task specification 810 may comprise softwareobjects or data structures, such as C++ objects, which may specify themeasurement task. In one embodiment, the measurement task specifier 810may be a measurement task wizard, i.e., a software program which leadsthe user through a measurement task specification process to create themeasurement task specification 860. In another embodiment, themeasurement task specifier 810 may take the form of a measurement taskconfigurator, which is a software program invocable by the user under adevelopment environment, such as the National Instruments LabVIEWenvironment or Measurement Studio programming development environment.In yet another embodiment, the measurement task specifier 810 may simplybe an API through which the user makes calls to generate the taskspecification. Thus, in various embodiments, the measurement taskspecifier 810 may generate the measurement task specification 860 inresponse to user input. As described above with reference to FIGS.5A-5D, the measurement task specifier 810 may be accessible to a user'sclient computer system 102 over a network 104.

As shown, the expert system 820A may use the measurement taskspecification 860 to generate a run time specification 865. In oneembodiment, the expert system 820A may include a plurality of experts.The expert system 820A may include one or more experts for each of themeasurement device types shown in FIGS. 2A, 2B, and 2C, as describedabove with reference to FIGS. 5A-5D. As also described above, the runtime specification may comprise parameter values for the hardware ormeasurement devices used to implement the measurement task.

FIG. 12B—Measurement Driver Program Components Including Run TimeBuilder

FIG. 12B illustrates various software components or programs 800Bcomprised in a measurement driver program, including a run time builder.The measurement driver shown in FIG. 12B is similar to that describedwith reference to FIG. 12A above, in that the measurement driver programincludes the measurement task specifier 810 and an expert system 820B,which may include one or more experts 822B. However, the expert systemof FIG. 12B may differ from that of FIG. 12A in that rather thangenerating a hardware configuration (and/or software), the expert system820B may generate a run time specification, described below.Additionally, the measurement driver program of FIG. 12B may alsoinclude a runtime builder 830, and various measurement primitives 840.The measurement driver program may also include other softwarecomponents as well.

As FIG. 12B also illustrates, various of the measurement driver programcomponents may be operable to generate respective products 850B whichmay be useable by other measurement driver program components, by othersoftware programs or systems, or by a user. In addition to themeasurement task specification 860, described above with reference toFIG. 12A, the measurement driver products 850B may include a run timespecification 865 and a run time 875, described below. Morespecifically, as shown in FIG. 12B, the expert system 820B may use themeasurement task specification 860 to generate the runtime specification865. Similar to the expert system 820A of above, the expert system 820Bmay include a plurality of experts, e.g., one or more experts for eachof the measurement device types shown in FIGS. 2A, 2B, and 2C.

In one embodiment, the runtime specification 865 may similarly comprisesoftware objects or data structures, such as C++ objects, which mayspecify the runtime parameters for software and/or hardware used toimplement the specified measurement task. The runtime specification 865may comprise parameter specifications for one or more measurementprimitives 840 which correspond to rudimentary measurement tasks oroperations. Said another way, the runtime specification 865 may comprisea collection of primitive settings, each of which may comprise adetailed and unambiguous “recipe” for a primitive. For example,primitive settings for a digitizer, such as a National InstrumentsE-Series digitizer, may include: Dither (Yes, No), Polarity (Bi-polar,Uni-polar), Gain, Mode (Calibration, Diff, NRSE, RSE, Aux, Ghost),Generate Trigger (Yes, No), and Last Channel (Yes, No). In oneembodiment, the run time specification may be used to configure hardwaredevices in the measurement system to perform the specified measurementtask.

In one embodiment, the run time specification 865 may in turn be useableby the runtime builder 830 to generate a run time 875, as shown, whichmay be executable to perform the specified measurement task. In otherwords, the run time 875 may be executable by the client computer system102 and/or one or more of the measurement devices to perform thespecified measurement task.

FIG. 13—Measurement Task Specifier Screen: Measurement Setup

As mentioned above, the measurement task specifier 730 may beimplemented in a variety of forms, including an API, a wizard, or ameasurement task configurator, among others. In one embodiment, themeasurement task specifier may comprise a software program, e.g., ameasurement task configurator, invocable by the user through a webbrowser. The measurement task configurator may comprise a graphical userinterface (GUI) which may provide an intuitive and powerful way for auser to specify a measurement task.

FIG. 13 illustrates an example configurator measurement setup interface,according to one embodiment. More specifically, FIG. 13 shows ameasurement setup interface for a voltage measurement. In oneembodiment, the primary panel, in this example titled “VoltageMeasurement Setup,” may be a main GUI template VI, configureddynamically for voltage measurement configuration. In one embodiment,this VI may be operable to receive user input specifying one or morebasic voltage measurements, including input ranges, sensors, andscaling, as shown. Various controls on the panel may also allow the userto add and remove measurements, as well as copying existingmeasurements. As shown, in one embodiment, the panel may also include alist of currently configured measurements of a given type, e.g., voltagemeasurements.

As FIG. 13 also shows, the configurator interface may include a blockspanel indicating the various types of measurement the user mayconfigure, such as voltage, temperature, resistance, frequency, andangular displacement, among others. In one embodiment, the user mayselect or click a particular block to activate the configuration panelsfor that type of measurement.

In one embodiment, the configurator interface may include an icon strip,shown in FIG. 13 between the blocks panel and the main panel. Each iconrepresents a configured group of measurements corresponding to one ofthe blocks in the block panel, such as voltage, temperature, frequency,etc. In another embodiment, each icon in the icon strip may represent astep or function of the measurement task being created. Thus, as theuser selects and configures measurement functions, corresponding iconsare added to the icon strip. It should be noted that each time ameasurement block is selected indicating a new measurement group, e.g.,a group of voltage measurements, an icon may be added to the icon strip.The measurements in each measurement group may be subject to thespecified parameters shown in the panel for that group, such as timing,triggering, routing, etc. If a user specifies multiple voltagemeasurement groups, then the icon for that measurement type (block) mayappear multiple times in the icon list. In one embodiment, when a userselects (clicks) an icon in the icon list, the configurator may presentone or more panels corresponding to that measurement group, therebyallowing the user to quickly access any measurement group specificationfor review, revision, replication, or deletion.

FIG. 14—Exemplary Configuration Diagram

FIG. 14 illustrates an exemplary graphical user interface, referred toas a configuration diagram, for deploying products on devices accordingto one embodiment.

The configuration diagram may include or display device icons thatrepresent the various devices in the distributed system. Each of thedevice icons preferably has an appearance which corresponds to thedevice it represents. This allows the viewer to easily view and considerwhat devices are present in the distributed system. Thus, in adistributed system which comprises two or more devices connected to eachother, such as through a network, a serial or parallel bus, or throughwireless means, etc., the system may display a device icon for each ofthe devices present in the system. For example, a computer system 102may be represented by a device icon that has the appearance of acomputer system. In a similar manner, other device icons may have anappearance which is similar to the appearance of the device itrepresents.

The configuration diagram may include or display connections(“connection icons”) such as lines, that are displayed between thevarious device icons to show the interrelationship or coupling betweenthe respective devices. The displayed connections may thus correspond tocouplings between the plurality of devices. In one embodiment, theconnections that are displayed may be context sensitive to indicate thetype of data or phenomena connected between the devices. In other words,the displayed connections between respective device icons have anappearance to visually indicate a type of connection between devicescorresponding to the respective device icons. For example, the displayedconnections may have an appearance that varies according to one or moreof color, size or shading to indicate the type of connection between thedevices. The appearance of the respective connections may indicatewhether the connection is a network connection, internal bus connection,external parallel bus connection, external serial bus connection (e.g.,USB or IEEE 1394) or a wireless connection. The appearance of therespective connections may also, or instead, indicate the type of dataor material flow between devices. In another embodiment, theconfiguration diagram may include labels displayed proximate to theconnections to visually indicate types of connection.

The user may at least partially create or assemble the configurationdiagram, or the configuration diagram may at least partially beautomatically or programmatically created, or both. In one embodiment,the configuration diagram may at least partly be automatically orprogrammatically created by the computer system 102 (or by the server103) based on an automatic detection of devices coupled to the computersystem 102. For example, the server 103 may automatically(programmatically) detect devices present in the measurement system andautomatically (programmatically) generate and display a correspondingconfiguration diagram. The configuration diagram may also be created atleast partly based on manual user input. For example, the user maymanually drag and drop device icons from a palette or menu to create theconfiguration diagram.

In one embodiment, the computer system 102 (or the server 103) mayautomatically detect devices and/or one or more couplings betweendevices present in the distributed system. The computer system 102 (orthe server 103) may then automatically display one or more device iconsand connections between respective device icons corresponding to the oneor more one or more couplings between devices automatically detected inthe distributed system. The connections between device icons that areautomatically displayed may be displayed with an appearance indicatingthe type of detected connection.

In one embodiment, the user may manually connect device icons on theconfiguration diagram, such as by using a pointing device. For example,in creating or modifying a configuration diagram, the user canassociate, e.g., drag and drop, or otherwise connect, a first deviceicon to a second device icon. For example, the user may use a pointingdevice (e.g., a mouse), and may possibly use a “wiring tool” icon on thedisplay, to connect a first device icon to a second device icon. Thismay cause a connection, e.g., a wire, to appear between the device iconsto indicate a relationship between the two (or more) device icons. Theconnection that is displayed between two device icons may be contextsensitive. In other words, the connection that is displayed or createdon the display may have a context or appearance that is associated withthe types of devices that are being connected. Alternatively, or inaddition, the connection that is displayed or created on the display mayhave a context or appearance that is associated with the type ofphysical connection (e.g., data or material flow) between the respectivedevices.

In a measurement application, the device icons may represent the variousmeasurement devices present in the system, such as those shown in FIGS.2A and 2B. For example, there may be device icons present for any one ormore of the various measurement or automation devices shown in FIGS. 2Aand 2B. Thus, as one example, where a computer system is coupled to aPXI chassis that includes a plurality of PXI instrument cards comprisedin the chassis, the configuration diagram may include a device iconwhich represents the computer system, and a device icon which representseach of the respective PXI instruments comprised in the PXI chassis. Theconfiguration diagram may also optionally include a device icon whichrepresents the PXI chassis, with further device icons comprised in thePXI chassis device icon representing each of the respective PXIinstrument cards. As another example, where one or more smart sensorsare present in the measurement system, icons may be present whichrepresent each of the various smart sensors. In a machine visionapplication, device icons may be present for a host computer system 82,an image acquisition board 134, and a camera 132, which may be a smartcamera as desired. Thus, the configuration diagram graphically displaysa plurality of device icons which represent the devices that are presentin the system, for which the user is desiring to configure or create anapplication.

The user may perform various operations using the configuration diagram.Alternatively, or in addition, the configuration diagram may be used todisplay operations performed by the server 103 and/or the computersystem 102.

For example, the user may select various program icons on the display(within or outside the configuration diagram) and associate them withvarious device icons (or other program icons) contained in theconfiguration diagram. This operation of associating program icons withdevice icons (or other program icons) in the configuration diagram mayoperate to deploy, either immediately or when the use selects “apply”,the respective programs on the various devices which correspond to thedevice icons (or within a program relationship or hierarchy representedby the program icons). Deploying a program may comprise moving orcopying the program from the server to a respective device, or moving orcopying the program between devices, among other types of operations.Various other deployment operations are also contemplated.

The operation of a user associating program icons with device icons (orother program icons) in the configuration diagram may be performed with“drag and drop” techniques, menu-based techniques, dialog boxtechniques, speech recognition techniques, or other techniques. Thisoperation of associating program icons with device icons (or otherprogram icons) in the configuration diagram operates to deploy, or causeto be deployed, the respective programs on the various devices whichcorrespond to the device icons. Thus, stated another way, if the userselects a first program icon and associates (e.g., drags and drops) thisfirst program icon on to a first device icon which represents a firstdevice, and the user optionally selects “apply”, this operates to deploya first program corresponding to that graphical program icon on to thefirst device which corresponds to that first device icon. This providesa greatly simplified mechanism for deploying programs on various devicesin a distributed system.

As another example, the configuration diagram may be animated to displayvarious deployments of products (programs and/or configurationinformation) to various devices in the system. For example, if theserver 103 is deploying a program to a device in the system, theconfiguration diagram may display the corresponding program icon movefrom a server icon representing the server to a device iconcorresponding to the device on which the program is being deployed.

The configuration diagram is preferably updated in real time as the user(or the server 103) performs iconic or deployment operations, such asthe deployment operations discussed above. Thus the configurationdiagram may display an iconic relationship view of the distributedprograms and distributed devices as the user associates (e.g., drags anddrops) the program icons on the device icons, the program icons on otherprogram icons, the device icons on other device icons, etc., or as theserver deploys programs. For example, as the user drags and dropsprogram icons (e.g., from the configuration diagram) on to variousdevice icons on the configuration diagram, or as the server 103 deploysprograms, the system may operate to display the relationship (e.g.,hierarchy) of programs proximate to, e.g., underneath, the respectivedevice icon to where they have been deployed.

In one embodiment, when the user associates program icons with variousdevice icons contained in the configuration diagram, the configurationdiagram is immediately updated accordingly, but this operation ofassociating does not operate to deploy programs at that time. Rather,the user may be required to select an “apply” feature for the deploymentto actually occur. This allows the user to view various configurationdiagram options before a deployment actually occurs. In anotherembodiment, a preview window may be employed to allow the user to viewproposed changes to a configuration diagram prior to the change beingcommitted or applied.

In one embodiment, when the user provides input to purchase a hardwareproduct from a vendor, the server 103 may cause the client computersystem configuration diagram to display a device icon (virtual deviceicon), where the virtual device icon has an alternate appearance(possibly “grayed out”) to indicate the device icon represents a virtualor non-present device. Program icons that are deployed to this virtualdevice icon may be stored in the computer system and deployed to thedevice when the device is received and installed in the system.

Thus, the above systems and methods may allow a user to access a serverover a network and specify a desired task, such as a measurement task,and receive configuration software and/or data, e.g., hardware and/orsoftware specifications, usable to configure the user's measurementsystem hardware (and/or software) to perform the desired task.Additionally, if the user does not have the hardware required to performthe task, the hardware specifications may be sent to a manufacturer, whomay then send the required hardware to the user. The configurationsoftware and/or data may be provided to the user for configuring thehardware. The hardware may be reconfigurable hardware, such as an FPGAor a processor/memory based device. In one embodiment, the requiredhardware may be pre-configured (using the configuration software and/ordata) to perform the task before being sent to the user. In anotherembodiment, the system and method may provide a graphical program to theuser in response to receiving the user's task specification, where thegraphical program may be usable by the measurement system to perform thetask.

The systems and methods described may benefit e-commerce vendors as wellas e-commerce users or customers, by increasing the reliability,consistency, and correctness of measurement system configuration withrespect to user task requirements, as well as substantially decreasingthe effort required from the user to implement the task, i.e., in theselection, configuration and ordering of measurement system productsusing the Internet.

EXAMPLE APPLICATIONS

The following describes examples of the use of various embodiments ofthe present invention. As one example, presume that the user operates ameasurement system wherein the measurement system comprises a computersystem (client computer system) and a reconfigurable instrument orreconfigurable measurement device coupled to or comprised in thecomputer system. For example, the measurement may comprise a computersystem and a reconfigurable measurement device card or reconfigurableinstrument card that is comprised in a PCI slot of the computer system,e.g., as shown in FIG. 2C. The user's computer system may also includeweb browser software for browsing the Internet.

The user may use the computer system to connect to the Internet andconnect to a server 103 as described herein. For example, the webbrowser on the user's client computer system may connect to a web serverat National Instruments Corporation. The client and/or the server mayexecute graphical user interface software which allows the user to entervarious user input into the client computer system. This user input mayspecify various requirements of the measurement function or measurementtask the user desires to create or configure. The user may enter thisuser input using a mouse, keyboard, speech recognition or other means.In response to this user input, information may be provided to theremote server, e.g., at National Instruments Corporation.

The client computer system may execute software which receives this userinput and generates a more detailed specification or a specificationformatted in a particular way. In another embodiment, the user inputprovided by the user is provided directly to the server computer system.For example, the server computer system may be executing the GUIsoftware and the user input may be provided directly to the server.Therefore, the measurement function or measurement task requirementsinput by the user are provided in some form to the server 103.

The server 103 receives these requirements and may perform any ofvarious operations. In one embodiment, the server 103 may query themeasurement system or client computer system to determine whatmeasurement devices and other hardware and/or software are currentlyconfigured in the user's measurement system. In another embodiment, theuser may also provide input with respect to the measurement devices andother hardware and/or software that are currently configured or in usein the user's measurement system.

The server 103 receives the requirements for the measurement task fromthe user and may operate to select and/or programmatically generate aprogram that is suited for the user's task. In one embodiment, theserver may simply select from one or more various pre-existing programsthat have been previously created. In another embodiment, the server 103may programmatically generate one or more programs “from scratch”without using any pre-existing programs. In another embodiment, theserver 103 may select among one or more various pre-existing programsand may further programmatically generate one or more other programs(and/or modify one or more existing programs) to generate a final set ofone or more programs that accomplishes at least a portion of or all ofthe user's specified measurement task or measurement function.

As one example, the server 103 may receive the requirements from theuser and programmatically generate a graphical program such as a LabVIEWVI in response to the requirements. This LabVIEW VI may then betransferred to the client computer system to configure the clientcomputer system or to one of the measurement devices in the measurementsystem. This LabVIEW VI may instead be transferred to the reconfigurablemeasurement device coupled to or comprised in the computer system. Thereconfigurable measurement device may have an IP address which allowsthe server 103 to directly configure the reconfigurable measurementdevice. Alternatively, the server 103 may programmatically generate agraphical program and then convert this graphical program into ahardware configuration program. This hardware configuration program maythen be provided to an FPGA comprised on the reconfigurable instrumentof the user.

If the reconfigurable measurement device comprised in the clientcomputer system includes a processor and memory, then the server 103 mayprovide a graphical program or a compiled executable program to thememory of the measurement device to configure the reconfigurablemeasurement device.

In one embodiment, the reconfigurable measurement device includes itsown IP address which the user may provide or which the server may queryand automatically determine, and the server may be operable toautomatically and programmatically configure the reconfigurablemeasurement device with a program of the appropriate type based on theuser's requirements. Thus the reconfigurable measurement device may havean IP address which allows the server 103 to directly configure thereconfigurable measurement device.

As another example, the measurement system may include a computer systemcoupled to a PXI chassis. The PXI chassis may include a firstreconfigurable measurement device that includes a processor and memoryand a second reconfigurable measurement device that includes an FPGA.The user may provide user input to the client computer, and variousmeasurement function or measurement task requirements are then providedto the server 103 as described above. The server 103 may then generate asoftware program, e.g., in source or executable form (e.g., a graphicalprogram) that is provided to the reconfigurable measurement device whichincludes the processor and memory. The server 103 may also provide ahardware configuration program and configure the hardware configurationprogram on the FPGA in the second reconfigurable measurement device.This operation of the server 103 configuring the reconfigurablemeasurement devices on the user's system may happen invisibly to theuser, or possibly may be indicated to the user with an animatedconfiguration diagram. The server 103 may also provide a notice to theuser that configuration is complete and operation may proceed.

In one embodiment of the invention, the server operates toprogrammatically generate graphical programs and then convert thesegenerated graphical programs to different program types depending on thetype of measurement devices present in the user's system.

As another example, assume the user has a computer system, one or moreinterface cards comprised in the computer system, such as dataacquisition cards, and one or more smart sensors coupled to the dataacquisition card(s). The smart sensors may include either a processorand memory or an FPGA. The user may use the methods described above toinput various requirements, and the server 103 may be operable togenerate and/or transfer one or more programs that are provided throughthe computer system to directly configure the one or more smart sensorsto perform a desired function. In one embodiment, the server 103provides the programs to the computer system, and the user executes areceived executable (or client-based configuration software) whichcauses the programs to be deployed on to the smart sensors. In anotherembodiment, the server 103 directly deploys respective programs on tothe smart sensors without any further involvement from the user. Forexample, each of the smart sensors may have an IP address for directcommunication.

In each of the above examples, the user may operate to inputrequirements and then receive programs that are deployed on hisrespective measurement devices. In an electronic commerce embodiment,the user may then submit payment information, such as a credit cardnumber and account number or other similar types of payment informationwhich pays the e-commerce vendor which operates the server 103 for thesedownloaded programs. The above methods provide a much more convenientway to select, purchase, and install measurement solutions, and othersolutions.

Remote Debugging Applications

In one embodiment of the invention, when the user has a configuredmeasurement system and is executing one or more graphical programs, theuser may desire to have an expert at a remote location debug operationof a portion or all of the measurement system. In one embodiment, ameasurement device in the user's measurement system may transferinformation regarding the block diagram that is contained within theuser's system. This block diagram information may be transferred to aserver, causing the block diagram executing in the measurement device tobe graphically displayed on the server computer system or a separatecomputer system. An expert located at the remote site may view thedisplayed block diagram as the respective block diagram implementexecutes in a measurement device that is remote from where the expert isviewing the block diagram. The expert may then use the block diagram asa GUI to implement various debugging operations such as single stepping,break points, and execution highlighting. Thus, a remote expert cangraphically view a block diagram that is executing at a remote locationfrom the expert, and the expert may be operable to provide or applyvarious debugging techniques to examine the block diagram as it executesat the remote location.

Programmatically Analyzing and Modifying a Graphical Program

In one embodiment, the server 103 may analyze a graphical program on theclient system 102 and may programmatically make changes to the graphicalprogram. For example, the server 103 may receive information on adesired measurement task, and then may programmatically makes changes tothe graphical program to modify the graphical program to perform theindicated measurement task. The server 103 may also programmaticallyanalyze a graphical program and then make suggestions or provide DLLs orother VIs for the user to incorporate into the graphical program, basedon the specified measurement task.

Software Emulation of a Device or Hardware Configuration Program

If the user elects to purchase or receive a FPGA bit file or hardwaredevice, during the interim the server 103 may send the client system asoftware program that may be used to simulate operation of the FPGA bitfile or hardware device that the user has ordered. Thus the user mayoperate the client system, using a software program executing on theclient computer CPU to perform the function of the FPGA bit file orhardware device that will be provided later. A configuration diagram maytemporarily display a software program icon to indicate that thisoperation is being performed. Alternatively, the configuration diagrammay temporarily display a device icon or program icon, corresponding tothe hardware device or bit file, respectively, with an alteredappearance to indicate that this function is being emulated by asoftware program. Once the FPGA bit file or hardware device is receivedby the client system, use of the software program may be discontinued.Also, the configuration diagram may change appropriately.

Network-Based Deployment, Analysis and Modification of Programs forOnline Configuration of a System

In one embodiment, the client system may provide information regardingits current configuration, including devices present and programs, tothe server 103 for analysis. For example, the user can provide asnapshot of the configuration of the measurement system and the softwareprograms (e.g., a LabVIEW VI) present in the system. The server 103 mayalso operate to programmatically obtain this information, with theuser's permission. The server 103 may receive this information andexecute software to make proposed suggestions to the user or actualmodifications to the client system's configuration or programs. Forexample, the server 103 may analyze the configuration and modify theprograms and provide a modified configuration back to the client system.The modified configuration or programs may then be returned to theclient system for use. The server 103 may thus iteratively examine theuser's system and make iterative changes to the system, as needed. Thusthe client 102 and the server 103 can communicate in a bi-directional,iterative fashion.

Network-Based System Which Provides a Database of Measurement Solutions

In one embodiment, the server 103 may operate to maintain a database ofsolutions which users may browse and access. Exemplary configurationdiagrams, programs, and other information for various typical systemsmay be stored in the database. In addition, when the server 103 receivesrequirements or task specifications from various users and generatessolutions, these solutions may also be stored in the database and beaccessible to subsequent users. The solutions stored in the database maycomprise configuration diagrams, configuration information and/orprograms, as well as other information. The database may also storerequirements provided by prior users and the corresponding solutionsgenerated in response to those requirements. Subsequent users may browsethis database for solutions to their desired tasks, possibly searchingbased on requirements, solution type, or other criteria. The server 103may also operate to receive requirements from a user and first operateto search the database for solutions. The server 103 mayprogrammatically generate a solution only if a pre-existing solution isnot found in the database.

Network-Based System for Selecting or Purchasing Products

In one embodiment, the user can connect to the server 103 and access adatabase of solutions such as described above. For example, the server103 may present a palette of icons representing items such asconfiguration diagrams, hardware devices, programs, and/or configurationinformation. The user can select an icon representing a configurationdiagram to indicate a desire to purchase hardware devices, programs,and/or configuration information required by or used in theconfiguration diagram. The user can also select icons representinghardware devices, programs, and/or configuration information to add toindicate a desired purchase. In one embodiment, the client system maydisplay a configuration diagram of the current client systemconfiguration, and the server may display a palette of iconsrepresenting items such as hardware devices, programs, and/orconfiguration information. The user can then associate (e.g., drag anddrop) hardware device icons from the palette displayed on the serveronto the configuration diagram displayed on the client system. This mayindicate that the user desires to purchase these hardware products. Theuser can also drag and drop program icons (or configuration informationicons) from the server palette onto the configuration diagram to deployprograms (or configuration information) from the server 103 on todevices in the client system. The user may also submit purchasinginformation to pay for purchased devices or programs.

Network-Based System for Specifying a Desired System Using aConfiguration Diagram

In one embodiment, the user may draw a configuration diagram of adesired system and send the configuration diagram to the server 103. Theserver 103 may analyze the configuration diagram and determineappropriate hardware devices, products and pricing information, whichmay then be transmitted back to the user of the client system. Forexample, the names of the devices, products and pricing information mayappear as textual or graphical data on the configuration diagram thatthe user may view (e.g., the prices of devices may appear below theirrespective device icons). If programs are suggested for purchase,program icons may appear on the configuration diagram. The user of theclient system may then choose the devices or products desired forpurchase. As a result, devices or programs represented in theconfiguration diagram may be shipped or electronically transferred tothe user.

Thus, embodiments of the present invention may provide a number ofbenefits to e-commerce vendors as well as e-commerce users or customers.First, the system and method may increase the amount of revenue fore-commerce vendors through increased closure and/or volume of purchases.In addition, the system and method may decrease the number of productreturns due to incorrectly configured products. The present inventionmay also provide a number of benefits to the user, including ease of usein the selection, configuration and ordering of products using theInternet, specifically measurement system products.

Although the embodiments above have been described in considerabledetail, numerous variations and modifications will become apparent tothose skilled in the art once the above disclosure is fully appreciated.It is intended that the following claims be interpreted to embrace allsuch variations and modifications.

1. A method for configuring a measurement system, comprising: receivinguser input indicating one or more requirements for a measurement task tobe performed by the measurement system, wherein the measurement systemcomprises at least one device; providing the one or more requirementsfor the measurement task to a server over a network; the serverautomatically generating at least one program based on the one or morerequirements, wherein the at least one program implements at least aportion of the measurement task, wherein said automatically generatingthe at least one program is performed without direct user inputspecifying the at least one program, wherein the at least one programincludes a graphical program comprising a plurality of interconnectednodes which visually indicates functionality of the graphical program,and wherein the server automatically generates the graphical programwithout direct user input selecting the plurality of nodes and withoutdirect user input specifying interconnections between the plurality ofnodes; the server downloading the at least one program over the network;and installing the at least one program on the at least one device;wherein said downloading and installing operate to configure themeasurement system to perform at least a portion of the measurementtask.
 2. The method of claim 1, wherein the at least one programincludes executable code which is executable by the measurement systemto perform the measurement task.
 3. The method of claim 1, wherein theat least one program includes source code which is: 1) compilable andexecutable, or 2) interpretable, by the measurement system to performthe measurement task.
 4. The method of claim 1, wherein the measurementsystem includes a graphical program execution engine for executing thegraphical program to perform the measurement task.
 5. The method ofclaim 1, wherein the measurement system comprises a client computersystem and at least one measurement device coupled to or comprised inthe client computer system; and wherein the at least one measurementdevice comprises a processor and memory for executing the at least oneprogram.
 6. The method of claim 1, wherein the at least one devicecomprises a client computer system and one or more measurement devicescoupled to or comprised in the client computer system.
 7. The method ofclaim 6, wherein said receiving user input and said providing the one ormore requirements are performed by the client computer system.
 8. Themethod of claim 6, wherein said downloading and said installing the atleast one program on the at least one device comprises: the serverdownloading the at least one program to the client computer system; andinstalling the at least one program on one or more of: the clientcomputer system; and the one or more measurement devices.
 9. The methodof claim 6, wherein the client computer system comprises a processor andmemory for executing at least a portion of the at least one program. 10.The method of claim 6, wherein the at least one program is executable bythe client computer system to perform the measurement task using the oneor more measurement devices.
 11. The method of claim 10, wherein the atleast one program includes machine executable code which is executableby the client computer system to perform the measurement task.
 12. Themethod of claim 10, wherein the at least one program includes sourcecode which is one or more of: 1) compilable and executable, or 2)interpretable, by the client computer system to perform the measurementtask.
 13. The method of claim 10, wherein the client computer systemincludes a graphical program execution engine for executing thegraphical program to perform the measurement task.
 14. The method ofclaim 6, wherein the measurement system comprises a client computersystem and at least one measurement device coupled to or comprised inthe client computer system; wherein the at least one program comprises aplurality of software programs; wherein the at least one measurementdevice is operable to execute a first one or more software programs toperform a first portion of the measurement task; and wherein the clientcomputer system is operable to execute a second one or more softwareprograms to perform a second portion of the measurement task.
 15. Themethod of claim 6, further comprising: displaying a graphical userinterface (GUI) on the client computer system, wherein the user inputindicating the one or more requirements for the measurement task isreceived to the GUI.
 16. The method of claim 15, wherein said displayingthe GUI comprises displaying a plurality of panels on the display toguide a user of the client computer system in providing the one or morerequirements for the measurement task.
 17. The method of claim 15,further comprising: the server providing the graphical user interface(GUI) to the client computer system over the network.
 18. The method ofclaim 6, wherein the measurement system includes a client computersystem, wherein the client computer system is coupled to the network;the method further comprising: the client computer system providingpayment information to pay for receipt of the configuration information.19. The method of claim 6, wherein the one or more requirements compriseinformation indicating types of the one or more measurement devices. 20.The method of claim 6, wherein the one or more requirements compriseinformation indicating desired operation of the one or more measurementdevices.
 21. The method of claim 6, wherein the one or more requirementscomprise information regarding one or more of signal type, samplingrate, timing, scaling, analysis function, and display function.
 22. Themethod of claim 6, wherein the one or more requirements comprise one ormore of: information indicating types of the one or more measurementdevices and information indicating desired operation of the one or moremeasurement devices; and wherein the server automatically generates atone program at least in part based on one or more of: informationindicating types of the one or more measurement devices and informationindicating desired operation of the one or more measurement devices. 23.The method of claim 6, further comprising: the server receivinginformation regarding the one or more measurement devices present in themeasurement system; wherein the server also generates the at least oneprogram based on the information regarding the one or more measurementdevices present in the measurement system.
 24. The method of claim 6,further comprising: the server automatically determining informationregarding the one or more measurement devices present in the measurementsystem; wherein the server also generates the at least one program basedon the information regarding the one or more measurement devices presentin the measurement system.
 25. The method of claim 6, furthercomprising: deploying the at least one program on the one or moremeasurement devices after said providing.
 26. The method of claim 1,wherein the one or more measurement devices comprise a plurality ofmeasurement devices wherein the one or more software programs comprisesa plurality of software programs; the method further comprising:deploying respective ones of the plurality of software programs onrespective ones of the plurality of measurement devices after saidproviding.
 27. The method of claim 1, wherein the one or morerequirements comprise information specifying one or more targetmeasurement devices to execute the one or more software programs;wherein the one or more measurement devices comprise a plurality ofmeasurement devices; and wherein the one or more software programscomprises a plurality of software programs; the method furthercomprising: deploying respective ones of the plurality of softwareprograms on respective ones of the plurality of measurement devicesafter said providing; wherein after said deploying a first measurementdevice is operable to execute a first one or more software programs toperform a first portion of the measurement task, and a secondmeasurement device is operable to execute a second one or more softwareprograms to perform a second portion of the measurement task.
 28. Themethod of claim 1, wherein the measurement system includes a clientcomputer system, the method further comprising: displaying a graphicaluser interface (GUI) on a display of the client computer system whichiconically illustrates the measurement system; and receiving user inputto the GUI specifying the one or more target measurement devices toexecute the at least one program.
 29. The method of claim 28, whereinsaid displaying the graphical user interface (GUI) on the display of theclient computer system which iconically illustrates the measurementsystem comprises: displaying one or more device icons corresponding torespective ones of the one or more measurement devices in themeasurement system; and displaying connections between the one or moredevice icons, wherein the displayed connections correspond to couplingsbetween the one or more measurement devices.
 30. The method of claim 28,further comprising: displaying one or more program icons associated withthe at least one program; and associating a first program icon with afirst device icon in response to user input, wherein the first programicon corresponds to a first program, wherein the first device iconcorresponds to a first device, wherein said associating operates tostore the first program on the first device.
 31. The method of claim 30,further comprising: displaying the first program icon proximate to thefirst device icon in response to said associating.
 32. The method ofclaim 1, wherein the at least one device comprises a reconfigurablemeasurement device; and wherein the reconfigurable measurement devicecomprises a processor and memory for executing at least a portion of theat least one program.
 33. The method of claim 1, further comprising: theserver determining configuration information in response to said one ormore requirements; and the server providing the configurationinformation to the measurement system over the network; wherein theconfiguration information is useable to configure the measurement systemto perform the measurement task.
 34. The method of claim 1, wherein themeasurement system comprises a programmable hardware element; the methodfurther comprising: the server determining a hardware configurationprogram in response to at least a portion of said one or morerequirements; and the server providing the hardware configurationprogram to the measurement system over the network; and wherein thehardware configuration program is usable for configuring theprogrammable hardware element to perform at least a portion of themeasurement task.
 35. The method of claim 1, further comprising: themeasurement system executing the at least one program to perform themeasurement function; wherein said executing the at least one program toperform the measurement function comprises: acquiring a signal from asignal source; and analyzing the signal after said acquiring.
 36. Themethod of claim 35, wherein the signal source comprises one or more of aunit under test (UUT), a sensor, and an actuator.
 37. The method ofclaim 1, further comprising: the server receiving payment information topay for receipt of the configuration information.
 38. The method ofclaim 1, wherein the one or more requirements comprise informationspecifying one or more target measurement devices to execute the atleast one program.
 39. The method of claim 1, wherein said installingthe at least one program on the at least one device is performed by oneor more of: a user of the measurement system; a client computer systemcoupled to or comprised in the measurement system; and the server.
 40. Acomputer accessible memory medium that stores program instructions forconfiguring a measurement system, wherein the program instructions areexecutable by a processor to implement: receiving user input indicatingone or more requirements for a measurement task to be performed by themeasurement system, wherein the measurement system comprises at leastone device; providing the one or more requirements for the measurementtask to a server over a network; the server automatically generating atleast one program based on the one or more requirements, wherein the atleast one program implements at least a portion of the measurement task,wherein the server performs said automatically generating the at leastone program without direct user input specifying the at least oneprogram, wherein the at least one program includes a graphical programcomprising a plurality of interconnected nodes which visually indicatesfunctionality of the graphical program, and wherein the serverautomatically generates the graphical program without direct user inputselecting the plurality of nodes and without direct user inputspecifying interconnections between the plurality of nodes; the serverdownloading the at least one program over the network; and installingthe at least one program on the at least one device; wherein saiddownloading and installing operate to configure the measurement systemto perform at least a portion of the measurement task.
 41. A system forconfiguring a measurement system, comprising: a first computer system,comprising: a first processor; a first memory medium coupled to theprocessor; and an input, coupled to the first memory medium and thefirst processor; wherein the input is operable to receive user inputindicating one or more requirements for a measurement task to beperformed by the measurement system, wherein the measurement systemcomprises at least one device; and wherein the first memory mediumstores program instructions that are executable by the processor to:provide the one or more requirements for the measurement task to aserver over a network; and the server, comprising: a second processor;and a second memory medium coupled to the second processor; wherein thesecond memory medium stores program instructions that are executable bythe second processor to: automatically generate at least one programbased on the one or more requirements, wherein the at least one programimplements at least a portion of the measurement task, wherein, inautomatically generating the at least one program, the programinstructions are executable by the second processor to automaticallygenerate at least one program without direct user input specifying theat least one program, wherein the at least one program includes agraphical program comprising a plurality of interconnected nodes whichvisually indicates functionality of the graphical program, and isautomatically generating the at least one program, the programinstructions are executable by the second processor to automaticallygenerate at least one the graphical program without direct user inputselecting the plurality of nodes and without direct user inputspecifying interconnections between the plurality of nodes; and downloadthe at least one program to the first computer system over the network;wherein the program instructions stored on the first memory mediumand/or the second memory medium are further executable by the firstprocessor and/or the second processor respectively to: install the atleast one program on the at least one device, thereby configuring themeasurement system to perform at least a portion of the measurementtask.
 42. A system for configuring a measurement system, comprising:means for receiving user input indicating one or more requirements for ameasurement task to be performed by the measurement system, wherein themeasurement system comprises at least one device; means for providingthe one or more requirements for the measurement task over a network;means for receiving the one or more requirements for the measurementtask over the network; means for automatically generating at least oneprogram based on the one or more requirements, wherein the at least oneprogram implements at least a portion of the measurement task, whereinsaid automatically generating the at least one program comprisesautomatically generating the at least one program without direct userinput specifying the at least one program wherein the at least oneprogram includes a graphical program comprising a plurality ofinterconnected nodes which visually indicates functionality of thegraphical program, and wherein said automatically generating the atleast one program comprises automatically generating at least oneprogram without direct user input selecting the plurality of nodes andwithout direct user input specifying interconnections between theplurality of nodes; means for downloading the at least one program overthe network; and means for installing the at least one program on the atleast one device; wherein said downloading and installing operate toconfigure the measurement system to perform at least a portion of themeasurement task.
 43. A method for configuring a measurement system,comprising: a server receiving one or more requirements for ameasurement task to be performed by the measurement system, wherein themeasurement system includes a computer system and at least onemeasurement device coupled to or comprised in the computer system,wherein the server receives the one or more requirements over a network;the server determining one or more software programs in response to theone or more requirements, wherein said determining the one or moresoftware programs comprises automatically determining the one or moresoftware programs without direct user input specifying the one or moreprograms wherein the one or more programs include at least one graphicalprogram comprising a plurality of interconnected nodes which visuallyindicates functionality of the graphical program, and wherein saiddetermining the one or more software programs comprises determining theat least one graphical program without direct user input selecting theplurality of nodes and without direct user input specifyinginterconnections between the plurality of nodes; and the serverproviding the one or more software programs to the computer system,wherein the one or more software programs are executable by themeasurement system to perform the measurement task; wherein themeasurement system is operable to execute the one or more softwareprograms to perform the measurement task after said providing.
 44. Themethod of claim 43, wherein the at least one measurement device isoperable to execute the one or more software programs to perform themeasurement task.
 45. The method of claim 43, wherein the clientcomputer system is operable to execute the one or more software programsto perform the measurement task.
 46. The method of claim 43, wherein theone or more software programs are executable by the client computersystem to perform the measurement task using the one or more measurementdevices.
 47. A method for configuring a system, comprising: a serverreceiving one or more requirements for a task to be performed by thesystem, wherein the system includes at least one device, wherein theserver receives the one or more requirements over a network; the serverautomatically generating one or more programs based on the one or morerequirements, wherein said automatically generating one or more programsis performed without direct user input specifying the one or moreprograms wherein the server automatically generating one or moreprograms comprises the server automatically generating at least onegraphical program based on the one or more requirements, wherein the atleast one graphical program comprises a plurality of interconnectednodes which visually indicate functionality of the graphical program,and wherein the server automatically generating the at least onegraphical program comprises the server automatically selecting andinterconnecting the plurality of nodes without direct user inputselecting the plurality of nodes and without direct user inputspecifying interconnections between the plurality of nodes; and theserver providing the one or more programs to the system over thenetwork; wherein the one or more programs are executable by the systemto perform the task.
 48. The method of claim 47, further comprising: theserver receiving payment information to pay for provision of the one ormore programs.
 49. The method of claim 47, wherein the task is ameasurement task; and wherein the device is a measurement device. 50.The method of claim 47, wherein the task is an automation task; andwherein the device is an automation device.
 51. The method of claim 47,wherein the task is a simulation task; and wherein the device is acomputer system.
 52. The method of claim 47, wherein the task is animage processing task; and wherein the device is an image processingdevice.
 53. The method of claim 47, wherein the task is a motion controltask; and wherein the device is a motion control device.
 54. The methodof claim 47, wherein the task is a network task; and wherein the deviceis a network device.
 55. A method for modeling a system, comprising: aserver receiving information for a model to be implemented by thesystem, wherein the server receives the information over a network; theserver determining at least one program in response to the information,wherein said determining the at least one program comprisesautomatically determining the at least one program without direct userinput specifying the at least one program, wherein the serverautomatically generating at least one program comprises the serverautomatically generating at least one graphical program based on thereceived information, wherein the at least one graphical programcomprises a plurality of interconnected nodes which visually indicatefunctionality of the graphical program,and wherein the serverautomatically generating at least one program comprises the serverautomatically selecting and interconnecting the plurality of nodeswithout direct user input selecting the plurality of nodes and withoutdirect user input specifying interconnections between the plurality ofnodes; and the server providing the at least one program to the systemover the network; wherein the at least one program is useable by thesystem to implement the model.
 56. The method of claim 55, wherein theserver determining at least one program comprises the serverautomatically generating at least one program based on the receivedinformation.
 57. The method of claim 55, further comprising: the serverreceiving payment information to pay for provision of the at least oneprogram.